// SPDX-License-Identifier: GPL-2.0 /* * Copyright (C) 2017-2018 Samsung Electronics Co., Ltd. */ #include "ufshcd.h" #include "ufstw.h" #include "ufs_quirks.h" #define UFS_MTK_TW_AWAYS_ON static int ufstw_create_sysfs(struct ufsf_feature *ufsf, struct ufstw_lu *tw); static int ufstw_clear_lu_flag(struct ufstw_lu *tw, u8 idn, bool *flag_res); static int ufstw_read_lu_attr(struct ufstw_lu *tw, u8 idn, u32 *attr_val); static inline void ufstw_lu_get(struct ufstw_lu *tw) { kref_get(&tw->ufsf->tw_kref); } static inline void ufstw_lu_put(struct ufstw_lu *tw) { kref_put(&tw->ufsf->tw_kref, ufstw_release); } static inline bool ufstw_is_write_lrbp(struct ufshcd_lrb *lrbp) { if (lrbp->cmd->cmnd[0] == WRITE_10 || lrbp->cmd->cmnd[0] == WRITE_16) return true; return false; } static int ufstw_switch_mode(struct ufstw_lu *tw, int tw_mode) { int ret = 0; atomic_set(&tw->tw_mode, tw_mode); if (tw->tw_enable) ret = ufstw_clear_lu_flag(tw, QUERY_FLAG_IDN_TW_EN, &tw->tw_enable); return ret; } static void ufstw_switch_disable_mode(struct ufstw_lu *tw) { WARNING_MSG("dTurboWriteBUfferLifeTImeEst 0x%X", tw->tw_lifetime_est); WARNING_MSG("tw-mode will change to disable-mode.."); mutex_lock(&tw->mode_lock); ufstw_switch_mode(tw, TW_MODE_DISABLED); mutex_unlock(&tw->mode_lock); } static void ufstw_lifetime_work_fn(struct work_struct *work) { struct ufstw_lu *tw; tw = container_of(work, struct ufstw_lu, tw_lifetime_work); ufstw_lu_get(tw); if (atomic_read(&tw->ufsf->tw_state) != TW_PRESENT) { INFO_MSG("tw_state != TW_PRESENT (%d)", atomic_read(&tw->ufsf->tw_state)); goto out; } if (ufstw_read_lu_attr(tw, QUERY_ATTR_IDN_TW_BUF_LIFETIME_EST, &tw->tw_lifetime_est)) goto out; #if defined(CONFIG_SCSI_UFS_TW_IGNORE_GUARANTEE_BIT) if (tw->tw_lifetime_est & MASK_UFSTW_LIFETIME_NOT_GUARANTEE) { WARNING_MSG("warn: lun %d - dTurboWriteBufferLifeTimeEst[31] == 1", tw->lun); WARNING_MSG("Device not guarantee the lifetime of Turbo Write Buffer"); WARNING_MSG("but we will ignore them for PoC"); } #else if (tw->tw_lifetime_est & MASK_UFSTW_LIFETIME_NOT_GUARANTEE) { WARNING_MSG("warn: lun %d - dTurboWriteBufferLifeTimeEst[31] == 1", tw->lun); WARNING_MSG("Device not guarantee the lifetime of Turbo Write Buffer"); WARNING_MSG("So tw_mode change to disable_mode"); goto tw_disable; } #endif if ((tw->tw_lifetime_est & ~MASK_UFSTW_LIFETIME_NOT_GUARANTEE) < UFSTW_MAX_LIFETIME_VALUE) goto out; else goto tw_disable; tw_disable: ufstw_switch_disable_mode(tw); out: ufstw_lu_put(tw); } void ufstw_prep_fn(struct ufsf_feature *ufsf, struct ufshcd_lrb *lrbp) { struct ufstw_lu *tw; if (!lrbp || !ufsf_is_valid_lun(lrbp->lun)) return; if (!ufstw_is_write_lrbp(lrbp)) return; tw = ufsf->tw_lup[lrbp->lun]; if (!tw) return; if (atomic_read(&tw->tw_mode) == TW_MODE_DISABLED) return; if (!tw->tw_enable) return; spin_lock_bh(&tw->lifetime_lock); tw->stat_write_sec += blk_rq_sectors(lrbp->cmd->request); if (tw->stat_write_sec > UFSTW_LIFETIME_SECT) { tw->stat_write_sec = 0; spin_unlock_bh(&tw->lifetime_lock); schedule_work(&tw->tw_lifetime_work); return; } blk_add_trace_msg(tw->ufsf->sdev_ufs_lu[tw->lun]->request_queue, "%s:%d tw_lifetime_work %u", __func__, __LINE__, tw->stat_write_sec); spin_unlock_bh(&tw->lifetime_lock); } static u8 ufstw_get_query_idx(struct ufstw_lu *tw) { u8 idx; /* Share buffer type only use idx 0 */ if (tw->ufsf->tw_dev_info.tw_buf_type == WB_SINGLE_SHARE_BUFFER_TYPE) idx = 0; else idx = (u8)tw->lun; return idx; } static int ufstw_read_lu_attr(struct ufstw_lu *tw, u8 idn, u32 *attr_val) { struct ufs_hba *hba = tw->ufsf->hba; int err; u32 val; u8 idx; pm_runtime_get_sync(hba->dev); ufstw_lu_get(tw); idx = ufstw_get_query_idx(tw); err = ufsf_query_attr_retry(hba, UPIU_QUERY_OPCODE_READ_ATTR, idn, idx, &val); if (err) { ERR_MSG("read attr [0x%.2X] failed...err %d", idn, err); ufstw_lu_put(tw); pm_runtime_put_sync(hba->dev); return err; } *attr_val = val; blk_add_trace_msg(tw->ufsf->sdev_ufs_lu[tw->lun]->request_queue, "%s:%d IDN %s (%d)", __func__, __LINE__, idn == QUERY_ATTR_IDN_TW_FLUSH_STATUS ? "TW_FLUSH_STATUS" : idn == QUERY_ATTR_IDN_TW_BUF_SIZE ? "TW_BUF_SIZE" : idn == QUERY_ATTR_IDN_TW_BUF_LIFETIME_EST ? "TW_BUF_LIFETIME_EST" : "UNKNOWN", idn); TW_DEBUG(tw->ufsf, "tw_attr LUN(%d) [0x%.2X] %u", tw->lun, idn, *attr_val); ufstw_lu_put(tw); pm_runtime_put_sync(hba->dev); return 0; } static int ufstw_set_lu_flag(struct ufstw_lu *tw, u8 idn, bool *flag_res) { struct ufs_hba *hba = tw->ufsf->hba; int err; u8 idx; pm_runtime_get_sync(hba->dev); ufstw_lu_get(tw); idx = ufstw_get_query_idx(tw); err = ufsf_query_flag_retry(hba, UPIU_QUERY_OPCODE_SET_FLAG, idn, idx, NULL); if (err) { ERR_MSG("set flag [0x%.2X] failed...err %d", idn, err); ufstw_lu_put(tw); pm_runtime_put_sync(hba->dev); return err; } *flag_res = true; blk_add_trace_msg(tw->ufsf->sdev_ufs_lu[tw->lun]->request_queue, "%s:%d IDN %s (%d)", __func__, __LINE__, idn == QUERY_FLAG_IDN_TW_EN ? "TW_EN" : idn == QUERY_FLAG_IDN_TW_BUF_FLUSH_EN ? "FLUSH_EN" : idn == QUERY_FLAG_IDN_TW_FLUSH_DURING_HIBERN ? "HIBERN_EN" : "UNKNOWN", idn); TW_DEBUG(tw->ufsf, "tw_flag LUN(%d) [0x%.2X] %u", tw->lun, idn, *flag_res); ufstw_lu_put(tw); pm_runtime_put_sync(hba->dev); return 0; } static int ufstw_clear_lu_flag(struct ufstw_lu *tw, u8 idn, bool *flag_res) { struct ufs_hba *hba = tw->ufsf->hba; int err; u8 idx; pm_runtime_get_sync(hba->dev); ufstw_lu_get(tw); idx = ufstw_get_query_idx(tw); err = ufsf_query_flag_retry(hba, UPIU_QUERY_OPCODE_CLEAR_FLAG, idn, idx, NULL); if (err) { ERR_MSG("clear flag [0x%.2X] failed...err%d", idn, err); ufstw_lu_put(tw); pm_runtime_put_sync(hba->dev); return err; } *flag_res = false; blk_add_trace_msg(tw->ufsf->sdev_ufs_lu[tw->lun]->request_queue, "%s:%d IDN %s (%d)", __func__, __LINE__, idn == QUERY_FLAG_IDN_TW_EN ? "TW_EN" : idn == QUERY_FLAG_IDN_TW_BUF_FLUSH_EN ? "FLUSH_EN" : idn == QUERY_FLAG_IDN_TW_FLUSH_DURING_HIBERN ? "HIBERN_EN" : "UNKNOWN", idn); TW_DEBUG(tw->ufsf, "tw_flag LUN(%d) [0x%.2X] %u", tw->lun, idn, *flag_res); ufstw_lu_put(tw); pm_runtime_put_sync(hba->dev); return 0; } static inline int ufstw_read_lu_flag(struct ufstw_lu *tw, u8 idn, bool *flag_res) { struct ufs_hba *hba = tw->ufsf->hba; int err; bool val = 0; u8 idx; pm_runtime_get_sync(hba->dev); ufstw_lu_get(tw); idx = ufstw_get_query_idx(tw); err = ufsf_query_flag_retry(hba, UPIU_QUERY_OPCODE_READ_FLAG, idn, idx, &val); if (err) { ERR_MSG("read flag [0x%.2X] failed...err%d", idn, err); ufstw_lu_put(tw); pm_runtime_put_sync(hba->dev); return err; } *flag_res = val; TW_DEBUG(tw->ufsf, "tw_flag LUN(%d) [0x%.2X] %u", tw->lun, idn, *flag_res); ufstw_lu_put(tw); pm_runtime_put_sync(hba->dev); return 0; } /* device level (ufsf) */ static int ufstw_auto_ee(struct ufsf_feature *ufsf) { struct ufs_hba *hba = ufsf->hba; u16 mask = MASK_EE_TW; u32 val; int err = 0; pm_runtime_get_sync(hba->dev); if (hba->ee_ctrl_mask & mask) goto out; val = hba->ee_ctrl_mask | mask; val &= 0xFFFF; /* 2 bytes */ err = ufsf_query_attr_retry(hba, UPIU_QUERY_OPCODE_WRITE_ATTR, QUERY_ATTR_IDN_EE_CONTROL, 0, &val); if (err) { ERR_MSG("failed to enable exception event err%d", err); goto out; } hba->ee_ctrl_mask |= mask; ufsf->tw_ee_mode = true; TW_DEBUG(ufsf, "turbo_write_exception_event_enable"); out: pm_runtime_put_sync(hba->dev); return err; } /* device level (ufsf) */ static int ufstw_disable_ee(struct ufsf_feature *ufsf) { struct ufs_hba *hba = ufsf->hba; u16 mask = MASK_EE_TW; int err = 0; u32 val; pm_runtime_get_sync(hba->dev); if (!(hba->ee_ctrl_mask & mask)) goto out; val = hba->ee_ctrl_mask & ~mask; val &= 0xFFFF; /* 2 bytes */ err = ufsf_query_attr_retry(hba, UPIU_QUERY_OPCODE_WRITE_ATTR, QUERY_ATTR_IDN_EE_CONTROL, 0, &val); if (err) { ERR_MSG("failed to disable exception event err%d", err); goto out; } hba->ee_ctrl_mask &= ~mask; ufsf->tw_ee_mode = false; TW_DEBUG(ufsf, "turbo_write_exeception_event_disable"); out: pm_runtime_put_sync(hba->dev); return err; } static void ufstw_flush_work_fn(struct work_struct *dwork) { struct ufs_hba *hba; struct ufstw_lu *tw; bool need_resched = false; tw = container_of(dwork, struct ufstw_lu, tw_flush_work.work); TW_DEBUG(tw->ufsf, "start flush worker"); ufstw_lu_get(tw); if (atomic_read(&tw->ufsf->tw_state) != TW_PRESENT) { ERR_MSG("tw_state != TW_PRESENT (%d)", atomic_read(&tw->ufsf->tw_state)); ufstw_lu_put(tw); return; } hba = tw->ufsf->hba; if (tw->next_q && time_before(jiffies, tw->next_q)) { if (schedule_delayed_work(&tw->tw_flush_work, tw->next_q - jiffies)) pm_runtime_get_noresume(hba->dev); ufstw_lu_put(tw); return; } pm_runtime_get_sync(hba->dev); if (ufstw_read_lu_attr(tw, QUERY_ATTR_IDN_TW_BUF_SIZE, &tw->tw_available_buffer_size)) goto error_put; mutex_lock(&tw->flush_lock); if (tw->tw_flush_during_hibern_enter && tw->tw_available_buffer_size >= tw->flush_th_max) { TW_DEBUG(tw->ufsf, "flush_disable QR (%d, %d)", tw->lun, tw->tw_available_buffer_size); if (ufstw_clear_lu_flag(tw, QUERY_FLAG_IDN_TW_FLUSH_DURING_HIBERN, &tw->tw_flush_during_hibern_enter)) goto error_unlock; tw->next_q = 0; need_resched = false; } else if (tw->tw_available_buffer_size < tw->flush_th_max) { if (tw->tw_flush_during_hibern_enter) { need_resched = true; } else if (tw->tw_available_buffer_size < tw->flush_th_min) { TW_DEBUG(tw->ufsf, "flush_enable QR (%d, %d)", tw->lun, tw->tw_available_buffer_size); if (ufstw_set_lu_flag(tw, QUERY_FLAG_IDN_TW_FLUSH_DURING_HIBERN, &tw->tw_flush_during_hibern_enter)) goto error_unlock; need_resched = true; } else { need_resched = false; } } mutex_unlock(&tw->flush_lock); pm_runtime_put_noidle(hba->dev); pm_runtime_put(hba->dev); if (need_resched) { tw->next_q = jiffies + msecs_to_jiffies(UFSTW_FLUSH_CHECK_PERIOD_MS); if (schedule_delayed_work(&tw->tw_flush_work, msecs_to_jiffies(UFSTW_FLUSH_CHECK_PERIOD_MS))) pm_runtime_get_noresume(hba->dev); } ufstw_lu_put(tw); return; error_unlock: mutex_unlock(&tw->flush_lock); error_put: pm_runtime_put_noidle(hba->dev); pm_runtime_put(hba->dev); if (tw->next_q) { tw->next_q = jiffies + msecs_to_jiffies(UFSTW_FLUSH_CHECK_PERIOD_MS); if (schedule_delayed_work(&tw->tw_flush_work, msecs_to_jiffies(UFSTW_FLUSH_CHECK_PERIOD_MS))) pm_runtime_get_noresume(hba->dev); } ufstw_lu_put(tw); } void ufstw_error_handler(struct ufsf_feature *ufsf) { ERR_MSG("tw_state : %d -> %d", atomic_read(&ufsf->tw_state), TW_FAILED); atomic_set(&ufsf->tw_state, TW_FAILED); dump_stack(); kref_put(&ufsf->tw_kref, ufstw_release); } void ufstw_ee_handler(struct ufsf_feature *ufsf) { struct ufs_hba *hba; int lun; hba = ufsf->hba; if (ufsf->tw_debug) atomic64_inc(&ufsf->tw_debug_ee_count); seq_scan_lu(lun) { if (!ufsf->tw_lup[lun]) continue; if (!ufsf->sdev_ufs_lu[lun]) { WARNING_MSG("warn: lun %d don't have scsi_device", lun); continue; } ufstw_lu_get(ufsf->tw_lup[lun]); if (!delayed_work_pending(&ufsf->tw_lup[lun]->tw_flush_work)) { ufsf->tw_lup[lun]->next_q = jiffies; if (schedule_delayed_work(&ufsf->tw_lup[lun]->tw_flush_work, msecs_to_jiffies(0))) pm_runtime_get_noresume(hba->dev); } ufstw_lu_put(ufsf->tw_lup[lun]); } } static void ufstw_flush_h8_work_fn(struct work_struct *dwork) { struct ufs_hba *hba; struct ufstw_lu *tw; tw = container_of(dwork, struct ufstw_lu, tw_flush_h8_work.work); hba = tw->ufsf->hba; /* Exit runtime suspend and do flush in hibern 1 sec */ pm_runtime_get_sync(hba->dev); msleep(1000); /* Check again, if still need flush reschedule itself */ if (ufstw_read_lu_attr(tw, QUERY_ATTR_IDN_TW_BUF_SIZE, &tw->tw_available_buffer_size)) { ERR_MSG("ERROR: get available tw buffer size error"); goto out; } if (tw->tw_available_buffer_size < tw->flush_th_max) schedule_delayed_work(&tw->tw_flush_h8_work, 0); out: pm_runtime_put_sync(hba->dev); } bool ufstw_need_flush(struct ufsf_feature *ufsf) { struct ufs_hba *hba = ufsf->hba; struct ufstw_lu *tw; bool need_flush = false; u8 idx; if (!ufsf->tw_lup[2]) goto out; if (!ufsf->sdev_ufs_lu[2]) { WARNING_MSG("warn: lun 2 don't have scsi_device"); goto out; } tw = ufsf->tw_lup[2]; if (atomic_read(&tw->tw_mode) == TW_MODE_DISABLED) goto out; if (!tw->tw_enable) goto out; if (atomic_read(&tw->ufsf->tw_state) != TW_PRESENT) goto out; ufstw_lu_get(tw); /* * No need check again, let ufstw_flush_h8_work_fn finish is enough. * Only return need_flush to break runtime/system suspend. */ if (work_busy(&tw->tw_flush_h8_work.work)) { need_flush = true; goto out_put; } idx = ufstw_get_query_idx(tw); if (ufsf_query_attr_retry(hba, UPIU_QUERY_OPCODE_READ_ATTR, QUERY_ATTR_IDN_TW_BUF_SIZE, idx, &tw->tw_available_buffer_size)) { ERR_MSG("ERROR: get available tw buffer size error"); goto out_put; } /* No need flush */ if (tw->tw_available_buffer_size >= tw->flush_th_max) goto out_put; /* Need flush, check device flush method */ if (hba->dev_quirks & UFS_DEVICE_QUIRK_WRITE_BOOSETER_FLUSH) { /* Toshiba device recover WB by toggle fWriteBoosterEn */ if (ufsf_query_flag_retry(hba, UPIU_QUERY_OPCODE_CLEAR_FLAG, QUERY_FLAG_IDN_TW_EN, idx, NULL)) { ERR_MSG("ERROR: disable tw error"); goto out_put; } if (ufsf_query_flag_retry(hba, UPIU_QUERY_OPCODE_SET_FLAG, QUERY_FLAG_IDN_TW_EN, idx, NULL)) { ERR_MSG("ERROR: enable tw error"); goto out_put; } } else { /* Other device recover WB by hibernate */ schedule_delayed_work(&tw->tw_flush_h8_work, 0); need_flush = true; } out_put: if (need_flush) { INFO_MSG("UFS TW available buffer size(%d) < %d0%%", tw->tw_available_buffer_size, tw->flush_th_max); } ufstw_lu_put(tw); out: return need_flush; } static inline void ufstw_init_dev_jobs(struct ufsf_feature *ufsf) { INIT_INFO("INIT_WORK(tw_reset_work)"); INIT_WORK(&ufsf->tw_reset_work, ufstw_reset_work_fn); } static inline void ufstw_init_lu_jobs(struct ufstw_lu *tw) { INIT_INFO("INIT_DELAYED_WORK(tw_flush_work) ufstw_lu%d", tw->lun); INIT_DELAYED_WORK(&tw->tw_flush_work, ufstw_flush_work_fn); INIT_DELAYED_WORK(&tw->tw_flush_h8_work, ufstw_flush_h8_work_fn); INIT_INFO("INIT_WORK(tw_lifetime_work)"); INIT_WORK(&tw->tw_lifetime_work, ufstw_lifetime_work_fn); } static inline void ufstw_cancel_lu_jobs(struct ufstw_lu *tw) { int ret; ret = cancel_delayed_work_sync(&tw->tw_flush_work); ret = cancel_work_sync(&tw->tw_lifetime_work); } void ufstw_get_dev_info(struct ufstw_dev_info *tw_dev_info, u8 *desc_buf) { struct ufsf_feature *ufsf; struct ufs_hba *hba; ufsf = container_of(tw_dev_info, struct ufsf_feature, tw_dev_info); hba = ufsf->hba; tw_dev_info->tw_device = false; if (UFSF_EFS_TURBO_WRITE & LI_EN_32(&desc_buf[DEVICE_DESC_PARAM_EX_FEAT_SUP])) INIT_INFO("bUFSExFeaturesSupport: TW support"); else { INIT_INFO("bUFSExFeaturesSupport: TW not support"); return; } tw_dev_info->tw_buf_no_reduct = desc_buf[DEVICE_DESC_PARAM_TW_RETURN_TO_USER]; tw_dev_info->tw_buf_type = desc_buf[DEVICE_DESC_PARAM_TW_BUF_TYPE]; /* Set TW device if TW support */ tw_dev_info->tw_device = true; INFO_MSG("tw_dev [53] bTurboWriteBufferNoUserSpaceReductionEn %u", tw_dev_info->tw_buf_no_reduct); INFO_MSG("tw_dev [54] bTurboWriteBufferType %u", tw_dev_info->tw_buf_type); } void ufstw_get_geo_info(struct ufstw_dev_info *tw_dev_info, u8 *geo_buf) { tw_dev_info->tw_number_lu = geo_buf[GEOMETRY_DESC_TW_NUMBER_LU]; if (tw_dev_info->tw_number_lu == 0) { ERR_MSG("Turbo Write is not supported"); tw_dev_info->tw_device = false; return; } INFO_MSG("tw_geo [4F:52] dTurboWriteBufferMaxNAllocUnits %u", LI_EN_32(&geo_buf[GEOMETRY_DESC_TW_MAX_SIZE])); INFO_MSG("tw_geo [53] bDeviceMaxTurboWriteLUs %u", tw_dev_info->tw_number_lu); INFO_MSG("tw_geo [54] bTurboWriteBufferCapAdjFac %u", geo_buf[GEOMETRY_DESC_TW_CAP_ADJ_FAC]); INFO_MSG("tw_geo [55] bSupportedTurboWriteBufferUserSpaceReductionTypes %u", geo_buf[GEOMETRY_DESC_TW_SUPPORT_USER_REDUCTION_TYPES]); INFO_MSG("tw_geo [56] bSupportedTurboWriteBufferTypes %u", geo_buf[GEOMETRY_DESC_TW_SUPPORT_BUF_TYPE]); } int ufstw_get_lu_info(struct ufsf_feature *ufsf, unsigned int lun, u8 *lu_buf) { struct ufsf_lu_desc lu_desc; struct ufstw_lu *tw; lu_desc.tw_lu_buf_size = LI_EN_32(&lu_buf[UNIT_DESC_TW_LU_MAX_BUF_SIZE]); ufsf->tw_lup[lun] = NULL; /* MTK: tw_buf_type = 0(LU base), 1(Single share) */ if ((lu_desc.tw_lu_buf_size) || ((ufsf->tw_dev_info.tw_buf_type == WB_SINGLE_SHARE_BUFFER_TYPE) && (lun == 2))) { ufsf->tw_lup[lun] = kzalloc(sizeof(struct ufstw_lu), GFP_KERNEL); if (!ufsf->tw_lup[lun]) return -ENOMEM; tw = ufsf->tw_lup[lun]; tw->ufsf = ufsf; tw->lun = lun; INIT_INFO("tw_lu LUN(%d) [29:2C] dLUNumTurboWriteBufferAllocUnits %u", lun, lu_desc.tw_lu_buf_size); } else { INIT_INFO("tw_lu LUN(%d) [29:2C] dLUNumTurboWriteBufferAllocUnits %u", lun, lu_desc.tw_lu_buf_size); INIT_INFO("===== LUN(%d) is TurboWrite-disabled.", lun); return -ENODEV; } return 0; } static inline void ufstw_print_lu_flag_attr(struct ufstw_lu *tw) { INFO_MSG("tw_flag LUN(%d) [%u] fTurboWriteEn %u", tw->lun, QUERY_FLAG_IDN_TW_EN, tw->tw_enable); INFO_MSG("tw_flag LUN(%d) [%u] fTurboWriteBufferFlushEn %u", tw->lun, QUERY_FLAG_IDN_TW_BUF_FLUSH_EN, tw->tw_flush_enable); INFO_MSG("tw_flag LUN(%d) [%u] fTurboWriteBufferFlushDuringHibernateEnter %u", tw->lun, QUERY_FLAG_IDN_TW_FLUSH_DURING_HIBERN, tw->tw_flush_during_hibern_enter); INFO_MSG("tw_attr LUN(%d) [%u] flush_status %u", tw->lun, QUERY_ATTR_IDN_TW_FLUSH_STATUS, tw->tw_flush_status); INFO_MSG("tw_attr LUN(%d) [%u] buffer_size %u", tw->lun, QUERY_ATTR_IDN_TW_BUF_SIZE, tw->tw_available_buffer_size); INFO_MSG("tw_attr LUN(%d) [%d] bufffer_lifetime %u(0x%X)", tw->lun, QUERY_ATTR_IDN_TW_BUF_LIFETIME_EST, tw->tw_lifetime_est, tw->tw_lifetime_est); } static inline void ufstw_lu_update(struct ufstw_lu *tw) { ufstw_lu_get(tw); /* Flag */ if (ufstw_read_lu_flag(tw, QUERY_FLAG_IDN_TW_EN, &tw->tw_enable)) goto error_put; if (ufstw_read_lu_flag(tw, QUERY_FLAG_IDN_TW_BUF_FLUSH_EN, &tw->tw_flush_enable)) goto error_put; if (ufstw_read_lu_flag(tw, QUERY_FLAG_IDN_TW_FLUSH_DURING_HIBERN, &tw->tw_flush_during_hibern_enter)) goto error_put; /* Attribute */ if (ufstw_read_lu_attr(tw, QUERY_ATTR_IDN_TW_FLUSH_STATUS, &tw->tw_flush_status)) goto error_put; if (ufstw_read_lu_attr(tw, QUERY_ATTR_IDN_TW_BUF_SIZE, &tw->tw_available_buffer_size)) goto error_put; ufstw_read_lu_attr(tw, QUERY_ATTR_IDN_TW_BUF_LIFETIME_EST, &tw->tw_lifetime_est); error_put: ufstw_lu_put(tw); } static void ufstw_lu_init(struct ufsf_feature *ufsf, unsigned int lun) { struct ufstw_lu *tw = ufsf->tw_lup[lun]; ufstw_lu_get(tw); tw->ufsf = ufsf; mutex_init(&tw->flush_lock); mutex_init(&tw->mode_lock); spin_lock_init(&tw->lifetime_lock); tw->stat_write_sec = 0; atomic_set(&tw->active_cnt, 0); tw->flush_th_min = UFSTW_FLUSH_WORKER_TH_MIN; tw->flush_th_max = UFSTW_FLUSH_WORKER_TH_MAX; /* for Debug */ ufstw_init_lu_jobs(tw); if (ufstw_create_sysfs(ufsf, tw)) INIT_INFO("sysfs init fail. but tw could run normally."); /* Read Flag, Attribute */ ufstw_lu_update(tw); #if defined(CONFIG_SCSI_UFS_TW_IGNORE_GUARANTEE_BIT) if (tw->tw_lifetime_est & MASK_UFSTW_LIFETIME_NOT_GUARANTEE) { WARNING_MSG("warn: lun %d - dTurboWriteBufferLifeTimeEst[31] == 1", lun); WARNING_MSG("Device not guarantee the lifetime of Turbo Write Buffer"); WARNING_MSG("but we will ignore them for PoC"); } #else if (tw->tw_lifetime_est & MASK_UFSTW_LIFETIME_NOT_GUARANTEE) { WARNING_MSG("warn: lun %d - dTurboWriteBufferLifeTimeEst[31] == 1", lun); WARNING_MSG("Device not guarantee the lifetime of Turbo Write Buffer"); WARNING_MSG("So tw_mode change to disable_mode"); goto tw_disable; } #endif if ((tw->tw_lifetime_est & ~MASK_UFSTW_LIFETIME_NOT_GUARANTEE) < UFSTW_MAX_LIFETIME_VALUE) { atomic_set(&tw->tw_mode, TW_MODE_MANUAL); goto out; } else goto tw_disable; tw_disable: ufstw_switch_disable_mode(tw); out: ufstw_print_lu_flag_attr(tw); ufstw_lu_put(tw); } void ufstw_init(struct ufsf_feature *ufsf) { unsigned int lun; unsigned int tw_enabled_lun = 0; #ifdef UFS_MTK_TW_AWAYS_ON int tw_lun = 0; struct ufstw_lu *tw; #endif kref_init(&ufsf->tw_kref); #ifdef UFS_MTK_TW_AWAYS_ON /* MTK: TW only enable in LU2, skip scan */ lun = 2; if (ufsf->tw_lup[lun]) { ufstw_lu_init(ufsf, lun); tw_lun = lun; INIT_INFO("UFSTW LU %d working", lun); tw_enabled_lun++; } #else seq_scan_lu(lun) { if (!ufsf->tw_lup[lun]) continue; if (!ufsf->sdev_ufs_lu[lun]) { WARNING_MSG("warn: lun %d don't have scsi_device", lun); continue; } ufstw_lu_init(ufsf, lun); ufsf->sdev_ufs_lu[lun]->request_queue->turbo_write_dev = true; INIT_INFO("UFSTW LU %d working", lun); tw_enabled_lun++; } #endif if (tw_enabled_lun == 0) { ERR_MSG("ERROR: tw_enabled_lun == 0. So TW disabled."); goto out_free_mem; } if (tw_enabled_lun > ufsf->tw_dev_info.tw_number_lu) { ERR_MSG("ERROR: dev_info(bDeviceMaxTurboWriteLUs) mismatch. So TW disabled."); goto out; } #ifdef UFS_MTK_TW_AWAYS_ON /* MTK: Disable TW if run out lifetime */ tw = ufsf->tw_lup[tw_lun]; if (atomic_read(&tw->tw_mode) == TW_MODE_DISABLED) goto out; #endif /* * Initialize Device Level... */ ufstw_disable_ee(ufsf); ufstw_init_dev_jobs(ufsf); atomic64_set(&ufsf->tw_debug_ee_count, 0); ufsf->tw_debug = false; atomic_set(&ufsf->tw_state, TW_PRESENT); #ifdef UFS_MTK_TW_AWAYS_ON /* MTK: Enable TW and H8 flush in Manual mode */ if ((atomic_read(&tw->tw_mode) == TW_MODE_MANUAL) && (tw_lun != 0)) { if (ufstw_set_lu_flag(tw, QUERY_FLAG_IDN_TW_EN, &tw->tw_enable)) goto out; if (ufstw_set_lu_flag(tw, QUERY_FLAG_IDN_TW_FLUSH_DURING_HIBERN, &tw->tw_flush_during_hibern_enter)) goto out; } #endif return; out_free_mem: seq_scan_lu(lun) { kfree(ufsf->tw_lup[lun]); ufsf->tw_lup[lun] = NULL; } out: /* MTK: not free because we still need querry */ ufsf->tw_dev_info.tw_device = false; atomic_set(&ufsf->tw_state, TW_NOT_SUPPORTED); } static inline int ufstw_probe_lun_done(struct ufsf_feature *ufsf) { return (ufsf->num_lu == ufsf->slave_conf_cnt); } void ufstw_init_work_fn(struct work_struct *work) { struct ufsf_feature *ufsf; #ifndef UFS_MTK_TW_AWAYS_ON int ret; #endif ufsf = container_of(work, struct ufsf_feature, tw_init_work); #ifndef UFS_MTK_TW_AWAYS_ON /* MTK: TW only enable in LU2, skip wait */ init_waitqueue_head(&ufsf->tw_wait); ret = wait_event_timeout(ufsf->tw_wait, ufstw_probe_lun_done(ufsf), msecs_to_jiffies(10000)); if (ret == 0) { ERR_MSG("Probing LU is not fully completed."); return; } #endif INIT_INFO("TW_INIT_START"); ufstw_init(ufsf); } void ufstw_suspend(struct ufsf_feature *ufsf) { struct ufstw_lu *tw; int lun; #if 0 int ret; /* * MTK: No ned flush work, else deadlock may happen. * flush_work ->ufstw_reset_work_fn -> ufstw_reset -> ufstw_set_lu_flag -> * pm_runtime_put_sync -> ufstw_suspend -> flush_work * Beside, reset work only set tw flag, it can do later after suspend. */ ret = flush_work(&ufsf->tw_reset_work); TW_DEBUG(ufsf, "flush_work(tw_reset_work) = %d", ret); #endif seq_scan_lu(lun) { tw = ufsf->tw_lup[lun]; if (!tw) continue; ufstw_lu_get(tw); ufstw_cancel_lu_jobs(tw); ufstw_lu_put(tw); } } void ufstw_resume(struct ufsf_feature *ufsf) { struct ufstw_lu *tw; int lun; seq_scan_lu(lun) { tw = ufsf->tw_lup[lun]; if (!tw) continue; ufstw_lu_get(tw); TW_DEBUG(ufsf, "ufstw_lu %d resume", lun); if (tw->next_q) { TW_DEBUG(ufsf, "ufstw_lu %d flush_worker reschedule...", lun); if (schedule_delayed_work(&tw->tw_flush_work, (tw->next_q - jiffies))) pm_runtime_get_noresume(ufsf->hba->dev); } ufstw_lu_put(tw); } } void ufstw_release(struct kref *kref) { struct ufsf_feature *ufsf; struct ufstw_lu *tw; int lun; int ret; dump_stack(); ufsf = container_of(kref, struct ufsf_feature, tw_kref); RELEASE_INFO("start release"); RELEASE_INFO("tw_state : %d -> %d", atomic_read(&ufsf->tw_state), TW_FAILED); atomic_set(&ufsf->tw_state, TW_FAILED); RELEASE_INFO("kref count %d", atomic_read(&ufsf->tw_kref.refcount.refs)); ret = cancel_work_sync(&ufsf->tw_reset_work); RELEASE_INFO("cancel_work_sync(tw_reset_work) = %d", ret); seq_scan_lu(lun) { tw = ufsf->tw_lup[lun]; RELEASE_INFO("ufstw_lu%d %p", lun, tw); ufsf->tw_lup[lun] = NULL; if (!tw) continue; ufstw_cancel_lu_jobs(tw); tw->next_q = 0; ret = kobject_uevent(&tw->kobj, KOBJ_REMOVE); RELEASE_INFO("kobject error %d", ret); kobject_del(&tw->kobj); kfree(tw); } RELEASE_INFO("end release"); } static void ufstw_reset(struct ufsf_feature *ufsf) { struct ufstw_lu *tw; int lun; int ret; if (atomic_read(&ufsf->tw_state) == TW_FAILED) { ERR_MSG("tw_state == TW_FAILED(%d)", atomic_read(&ufsf->tw_state)); return; } seq_scan_lu(lun) { tw = ufsf->tw_lup[lun]; TW_DEBUG(ufsf, "reset tw[%d]=%p", lun, tw); if (!tw) continue; INFO_MSG("ufstw_lu%d reset", lun); ufstw_lu_get(tw); ufstw_cancel_lu_jobs(tw); if (atomic_read(&tw->tw_mode) == TW_MODE_MANUAL && tw->tw_enable) { ret = ufstw_set_lu_flag(tw, QUERY_FLAG_IDN_TW_EN, &tw->tw_enable); if (ret) tw->tw_enable = false; } if (tw->tw_flush_enable) { ret = ufstw_set_lu_flag(tw, QUERY_FLAG_IDN_TW_BUF_FLUSH_EN, &tw->tw_flush_enable); if (ret) tw->tw_flush_enable = false; } if (tw->tw_flush_during_hibern_enter) { ret = ufstw_set_lu_flag(tw, QUERY_FLAG_IDN_TW_FLUSH_DURING_HIBERN, &tw->tw_flush_during_hibern_enter); if (ret) tw->tw_flush_during_hibern_enter = false; } if (tw->next_q) { TW_DEBUG(ufsf, "ufstw_lu %d flush_worker reschedule...", lun); if (schedule_delayed_work(&tw->tw_flush_work, (tw->next_q - jiffies))) pm_runtime_get_noresume(ufsf->hba->dev); } ufstw_lu_put(tw); } if (ufsf->tw_ee_mode) ufstw_auto_ee(ufsf); atomic_set(&ufsf->tw_state, TW_PRESENT); INFO_MSG("reset complete.. tw_state %d", atomic_read(&ufsf->tw_state)); } static inline int ufstw_wait_kref_init_value(struct ufsf_feature *ufsf) { return (atomic_read(&ufsf->tw_kref.refcount.refs) == 1); } void ufstw_reset_work_fn(struct work_struct *work) { struct ufsf_feature *ufsf; int ret; ufsf = container_of(work, struct ufsf_feature, tw_reset_work); /* * If down eh_sem and runtime resume fail, it will block eh_work and * cause deadlock. * 1. eh_work wait eh_sem * 2. tw_reset_work wait runtime resume * 3. rumtime resume wait eh_work do link recovery * Here make sure runtime resume success. */ pm_runtime_get_sync(ufsf->hba->dev); down(&ufsf->hba->eh_sem); TW_DEBUG(ufsf, "reset tw_kref.refcount=%d", atomic_read(&ufsf->tw_kref.refcount.refs)); init_waitqueue_head(&ufsf->tw_wait); ret = wait_event_timeout(ufsf->tw_wait, ufstw_wait_kref_init_value(ufsf), msecs_to_jiffies(15000)); if (ret == 0) { ERR_MSG("UFSTW kref is not init_value(=1). kref count = %d ret = %d. So, TW_RESET_FAIL", atomic_read(&ufsf->tw_kref.refcount.refs), ret); up(&ufsf->hba->eh_sem); pm_runtime_put_sync(ufsf->hba->dev); return; } INIT_INFO("TW_RESET_START"); ufstw_reset(ufsf); up(&ufsf->hba->eh_sem); pm_runtime_put_sync(ufsf->hba->dev); } /* protected by mutex mode_lock */ static void __active_turbo_write(struct ufstw_lu *tw, int do_work) { if (atomic_read(&tw->tw_mode) != TW_MODE_FS) return; blk_add_trace_msg(tw->ufsf->sdev_ufs_lu[tw->lun]->request_queue, "%s:%d do_work %d active_cnt %d", __func__, __LINE__, do_work, atomic_read(&tw->active_cnt)); if (do_work == TW_FLAG_ENABLE_SET && !tw->tw_enable) ufstw_set_lu_flag(tw, QUERY_FLAG_IDN_TW_EN, &tw->tw_enable); else if (do_work == TW_FLAG_ENABLE_CLEAR && tw->tw_enable) ufstw_clear_lu_flag(tw, QUERY_FLAG_IDN_TW_EN, &tw->tw_enable); } static void ufstw_active_turbo_write(struct request_queue *q, bool on) { struct scsi_device *sdev = q->queuedata; struct Scsi_Host *shost; struct ufs_hba *hba; struct ufstw_lu *tw; int do_work = TW_FLAG_ENABLE_NONE; u64 lun; lun = sdev->lun; if (lun >= UFS_UPIU_MAX_GENERAL_LUN) return; shost = sdev->host; hba = shost_priv(shost); tw = hba->ufsf.tw_lup[lun]; if (!tw) return; ufstw_lu_get(tw); if (on) { if (atomic_inc_return(&tw->active_cnt) == 1) do_work = TW_FLAG_ENABLE_SET; } else { if (atomic_dec_return(&tw->active_cnt) == 0) do_work = TW_FLAG_ENABLE_CLEAR; } blk_add_trace_msg(q, "%s:%d on %d active cnt %d do_work %d state %d mode %d", __func__, __LINE__, on, atomic_read(&tw->active_cnt), do_work, atomic_read(&tw->ufsf->tw_state), atomic_read(&tw->tw_mode)); if (!do_work) goto out; if (atomic_read(&tw->ufsf->tw_state) != TW_PRESENT) { WARNING_MSG("tw_state %d.. cannot enable turbo_write..", atomic_read(&tw->ufsf->tw_state)); goto out; } if (atomic_read(&tw->tw_mode) != TW_MODE_FS) goto out; mutex_lock(&tw->mode_lock); __active_turbo_write(tw, do_work); mutex_unlock(&tw->mode_lock); out: ufstw_lu_put(tw); } void bdev_set_turbo_write(struct block_device *bdev) { struct request_queue *q = bdev->bd_queue; blk_add_trace_msg(q, "%s:%d turbo_write_dev %d\n", __func__, __LINE__, q->turbo_write_dev); if (q->turbo_write_dev) ufstw_active_turbo_write(bdev->bd_queue, true); } void bdev_clear_turbo_write(struct block_device *bdev) { struct request_queue *q = bdev->bd_queue; blk_add_trace_msg(q, "%s:%d turbo_write_dev %d\n", __func__, __LINE__, q->turbo_write_dev); if (q->turbo_write_dev) ufstw_active_turbo_write(bdev->bd_queue, false); } /* sysfs function */ static ssize_t ufstw_sysfs_show_ee_mode(struct ufstw_lu *tw, char *buf) { SYSFS_INFO("TW_ee_mode %d", tw->ufsf->tw_ee_mode); return snprintf(buf, PAGE_SIZE, "%d", tw->ufsf->tw_ee_mode); } static ssize_t ufstw_sysfs_store_ee_mode(struct ufstw_lu *tw, const char *buf, size_t count) { unsigned long val = 0; if (kstrtoul(buf, 0, &val)) return -EINVAL; if (atomic_read(&tw->ufsf->tw_state) != TW_PRESENT) { SYSFS_INFO("ee_mode cannot change, because current state is not TW_PRESENT (%d)..", atomic_read(&tw->ufsf->tw_state)); return -EINVAL; } if (val >= TW_EE_MODE_NUM) { SYSFS_INFO("wrong input.. your input %lu", val); return -EINVAL; } if (val) ufstw_auto_ee(tw->ufsf); else ufstw_disable_ee(tw->ufsf); SYSFS_INFO("TW_ee_mode %d", tw->ufsf->tw_ee_mode); return count; } static ssize_t ufstw_sysfs_show_flush_during_hibern_enter(struct ufstw_lu *tw, char *buf) { int ret; mutex_lock(&tw->flush_lock); if (ufstw_read_lu_flag(tw, QUERY_FLAG_IDN_TW_FLUSH_DURING_HIBERN, &tw->tw_flush_during_hibern_enter)) { mutex_unlock(&tw->flush_lock); return -EINVAL; } SYSFS_INFO("TW_flush_during_hibern_enter %d", tw->tw_flush_during_hibern_enter); ret = snprintf(buf, PAGE_SIZE, "%d", tw->tw_flush_during_hibern_enter); mutex_unlock(&tw->flush_lock); return ret; } static ssize_t ufstw_sysfs_store_flush_during_hibern_enter(struct ufstw_lu *tw, const char *buf, size_t count) { unsigned long val = 0; if (kstrtoul(buf, 0, &val)) return -EINVAL; if (atomic_read(&tw->ufsf->tw_state) != TW_PRESENT) { SYSFS_INFO("tw_mode cannot change, because current state is not TW_PRESENT (%d)..", atomic_read(&tw->ufsf->tw_state)); return -EINVAL; } mutex_lock(&tw->flush_lock); if (tw->ufsf->tw_ee_mode == TW_EE_MODE_AUTO) { SYSFS_INFO("flush_during_hibern_enable cannot change on auto ee_mode"); mutex_unlock(&tw->flush_lock); return -EINVAL; } if (val) { if (ufstw_set_lu_flag(tw, QUERY_FLAG_IDN_TW_FLUSH_DURING_HIBERN, &tw->tw_flush_during_hibern_enter)) { mutex_unlock(&tw->flush_lock); return -EINVAL; } } else { if (ufstw_clear_lu_flag(tw, QUERY_FLAG_IDN_TW_FLUSH_DURING_HIBERN, &tw->tw_flush_during_hibern_enter)) { mutex_unlock(&tw->flush_lock); return -EINVAL; } } SYSFS_INFO("TW_flush_during_hibern_enter %d", tw->tw_flush_during_hibern_enter); mutex_unlock(&tw->flush_lock); return count; } static ssize_t ufstw_sysfs_show_flush_enable(struct ufstw_lu *tw, char *buf) { int ret; if (ufstw_read_lu_flag(tw, QUERY_FLAG_IDN_TW_BUF_FLUSH_EN, &tw->tw_flush_enable)) return -EINVAL; SYSFS_INFO("TW_flush_enable %d", tw->tw_flush_enable); ret = snprintf(buf, PAGE_SIZE, "%d", tw->tw_flush_enable); return ret; } static ssize_t ufstw_sysfs_store_flush_enable(struct ufstw_lu *tw, const char *buf, size_t count) { unsigned long val = 0; if (kstrtoul(buf, 0, &val)) return -EINVAL; if (atomic_read(&tw->ufsf->tw_state) != TW_PRESENT) { SYSFS_INFO("tw_mode cannot change, because current tw-state is not TW_PRESENT..(state:%d)..", atomic_read(&tw->ufsf->tw_state)); return -EINVAL; } if (tw->ufsf->tw_ee_mode == TW_EE_MODE_AUTO) { SYSFS_INFO("flush_enable cannot change on auto ee_mode"); return -EINVAL; } if (val) { if (ufstw_set_lu_flag(tw, QUERY_FLAG_IDN_TW_BUF_FLUSH_EN, &tw->tw_flush_enable)) return -EINVAL; } else { if (ufstw_clear_lu_flag(tw, QUERY_FLAG_IDN_TW_BUF_FLUSH_EN, &tw->tw_flush_enable)) return -EINVAL; } SYSFS_INFO("TW_flush_enable %d", tw->tw_flush_enable); return count; } static ssize_t ufstw_sysfs_show_debug(struct ufstw_lu *tw, char *buf) { SYSFS_INFO("debug %d", tw->ufsf->tw_debug); return snprintf(buf, PAGE_SIZE, "%d", tw->ufsf->tw_debug); } static ssize_t ufstw_sysfs_store_debug(struct ufstw_lu *tw, const char *buf, size_t count) { unsigned long val = 0; if (kstrtoul(buf, 0, &val)) return -EINVAL; if (val) tw->ufsf->tw_debug = true; else tw->ufsf->tw_debug = false; SYSFS_INFO("debug %d", tw->ufsf->tw_debug); return count; } static ssize_t ufstw_sysfs_show_flush_th_min(struct ufstw_lu *tw, char *buf) { SYSFS_INFO("flush_th_min%d", tw->flush_th_min); return snprintf(buf, PAGE_SIZE, "%d", tw->flush_th_min); } static ssize_t ufstw_sysfs_store_flush_th_min(struct ufstw_lu *tw, const char *buf, size_t count) { unsigned long val = 0; if (kstrtoul(buf, 0, &val)) return -EINVAL; if (val < 0 || val > 10) { SYSFS_INFO("input value is wrong.. your input %lu", val); return -EINVAL; } if (tw->flush_th_max <= val) { SYSFS_INFO("input value could not be greater than flush_th_max.."); SYSFS_INFO("your input %lu, flush_th_max %u", val, tw->flush_th_max); return -EINVAL; } tw->flush_th_min = val; SYSFS_INFO("flush_th_min %u", tw->flush_th_min); return count; } static ssize_t ufstw_sysfs_show_flush_th_max(struct ufstw_lu *tw, char *buf) { SYSFS_INFO("flush_th_max %d", tw->flush_th_max); return snprintf(buf, PAGE_SIZE, "%d", tw->flush_th_max); } static ssize_t ufstw_sysfs_store_flush_th_max(struct ufstw_lu *tw, const char *buf, size_t count) { unsigned long val = 0; if (kstrtoul(buf, 0, &val)) return -EINVAL; if (val < 0 || val > 10) { SYSFS_INFO("input value is wrong.. your input %lu", val); return -EINVAL; } if (tw->flush_th_min >= val) { SYSFS_INFO("input value could not be less than flush_th_min.."); SYSFS_INFO("your input %lu, flush_th_min %u", val, tw->flush_th_min); return -EINVAL; } tw->flush_th_max = val; SYSFS_INFO("flush_th_max %u", tw->flush_th_max); return count; } static ssize_t ufstw_sysfs_show_version(struct ufstw_lu *tw, char *buf) { SYSFS_INFO("TW version %.4X D/D version %.4X", tw->ufsf->tw_dev_info.tw_ver, UFSTW_DD_VER); return snprintf(buf, PAGE_SIZE, "TW version %.4X DD version %.4X", tw->ufsf->tw_dev_info.tw_ver, UFSTW_DD_VER); } static ssize_t ufstw_sysfs_show_debug_active_cnt(struct ufstw_lu *tw, char *buf) { SYSFS_INFO("debug active cnt %d", atomic_read(&tw->active_cnt)); return snprintf(buf, PAGE_SIZE, "active_cnt %d", atomic_read(&tw->active_cnt)); } /* SYSFS DEFINE */ #define define_sysfs_ro(_name) __ATTR(_name, 0444,\ ufstw_sysfs_show_##_name, NULL), #define define_sysfs_rw(_name) __ATTR(_name, 0644,\ ufstw_sysfs_show_##_name, \ ufstw_sysfs_store_##_name), #define define_sysfs_attr_r_function(_name, _IDN) \ static ssize_t ufstw_sysfs_show_##_name(struct ufstw_lu *tw, char *buf) \ { \ if (ufstw_read_lu_attr(tw, _IDN, &tw->tw_##_name))\ return -EINVAL;\ SYSFS_INFO("TW_"#_name" : %u (0x%X)", tw->tw_##_name, tw->tw_##_name); \ return snprintf(buf, PAGE_SIZE, "%u", tw->tw_##_name); \ } /* SYSFS FUNCTION */ define_sysfs_attr_r_function(flush_status, QUERY_ATTR_IDN_TW_FLUSH_STATUS) define_sysfs_attr_r_function(available_buffer_size, QUERY_ATTR_IDN_TW_BUF_SIZE) define_sysfs_attr_r_function(current_tw_buffer_size, QUERY_ATTR_CUR_TW_BUF_SIZE) define_sysfs_attr_r_function(lifetime_est, QUERY_ATTR_IDN_TW_BUF_LIFETIME_EST) static ssize_t ufstw_sysfs_show_tw_enable(struct ufstw_lu *tw, char *buf) { if (ufstw_read_lu_flag(tw, QUERY_FLAG_IDN_TW_EN, &tw->tw_enable)) return -EINVAL; SYSFS_INFO("TW_enable: %u (0x%X)", tw->tw_enable, tw->tw_enable); return snprintf(buf, PAGE_SIZE, "%u", tw->tw_enable); } static ssize_t ufstw_sysfs_store_tw_enable(struct ufstw_lu *tw, const char *buf, size_t count) { unsigned long val = 0; ssize_t ret = count; if (kstrtoul(buf, 0, &val)) return -EINVAL; if (val > 2) { SYSFS_INFO("wrong mode number.. your input %lu", val); return -EINVAL; } mutex_lock(&tw->mode_lock); if (atomic_read(&tw->tw_mode) == TW_MODE_DISABLED) { SYSFS_INFO("all turbo write life time is exhausted.."); SYSFS_INFO("you could not change this value.."); goto out; } if (atomic_read(&tw->tw_mode) != TW_MODE_MANUAL) { SYSFS_INFO("cannot set tw_enable.. current %s (%d) mode..", atomic_read(&tw->tw_mode) == TW_MODE_FS ? "TW_MODE_FS" : "UNKNOWN", atomic_read(&tw->tw_mode)); ret = -EINVAL; goto out; } if (val) { if (ufstw_set_lu_flag(tw, QUERY_FLAG_IDN_TW_EN, &tw->tw_enable)) { ret = -EINVAL; goto out; } } else { if (ufstw_clear_lu_flag(tw, QUERY_FLAG_IDN_TW_EN, &tw->tw_enable)) { ret = -EINVAL; goto out; } } out: mutex_unlock(&tw->mode_lock); SYSFS_INFO("TW_enable : %u (0x%X)", tw->tw_enable, tw->tw_enable); return ret; } static ssize_t ufstw_sysfs_show_tw_mode(struct ufstw_lu *tw, char *buf) { int tw_mode = atomic_read(&tw->tw_mode); SYSFS_INFO("TW_mode %s %d", tw_mode == TW_MODE_MANUAL ? "manual" : tw_mode == TW_MODE_FS ? "fs" : "unknown", tw_mode); return snprintf(buf, PAGE_SIZE, "%d", tw_mode); } static ssize_t ufstw_sysfs_store_tw_mode(struct ufstw_lu *tw, const char *buf, size_t count) { int tw_mode = 0; if (kstrtouint(buf, 0, &tw_mode)) return -EINVAL; if (atomic_read(&tw->ufsf->tw_state) != TW_PRESENT) { SYSFS_INFO("tw_mode cannot change, because current state is not TW_PRESENT (%d)..", atomic_read(&tw->ufsf->tw_state)); return -EINVAL; } if (tw_mode >= TW_MODE_NUM || tw_mode == TW_MODE_DISABLED) { SYSFS_INFO("wrong mode number.. your input %d", tw_mode); return -EINVAL; } mutex_lock(&tw->mode_lock); if (atomic_read(&tw->tw_mode) == TW_MODE_DISABLED) { SYSFS_INFO("all turbo write life time is exhausted.."); SYSFS_INFO("you could not change this value.."); count = -EINVAL; goto out; } if (tw_mode == atomic_read(&tw->tw_mode)) goto out; count = (ssize_t) ufstw_switch_mode(tw, tw_mode); out: mutex_unlock(&tw->mode_lock); SYSFS_INFO("TW_mode: %d", atomic_read(&tw->tw_mode)); return count; } static struct ufstw_sysfs_entry ufstw_sysfs_entries[] = { /* tw mode select */ define_sysfs_rw(tw_mode) /* Flag */ define_sysfs_rw(tw_enable) define_sysfs_rw(flush_enable) define_sysfs_rw(flush_during_hibern_enter) /* Attribute */ define_sysfs_rw(ee_mode) define_sysfs_ro(flush_status) define_sysfs_ro(available_buffer_size) define_sysfs_ro(current_tw_buffer_size) define_sysfs_ro(lifetime_est) /* debug */ define_sysfs_rw(debug) define_sysfs_ro(debug_active_cnt) /* support */ define_sysfs_rw(flush_th_max) define_sysfs_rw(flush_th_min) /* device level */ define_sysfs_ro(version) __ATTR_NULL }; static ssize_t ufstw_attr_show(struct kobject *kobj, struct attribute *attr, char *page) { struct ufstw_sysfs_entry *entry; struct ufstw_lu *tw; ssize_t error; entry = container_of(attr, struct ufstw_sysfs_entry, attr); tw = container_of(kobj, struct ufstw_lu, kobj); if (!entry->show) return -EIO; ufstw_lu_get(tw); mutex_lock(&tw->sysfs_lock); error = entry->show(tw, page); mutex_unlock(&tw->sysfs_lock); ufstw_lu_put(tw); return error; } static ssize_t ufstw_attr_store(struct kobject *kobj, struct attribute *attr, const char *page, size_t length) { struct ufstw_sysfs_entry *entry; struct ufstw_lu *tw; ssize_t error; entry = container_of(attr, struct ufstw_sysfs_entry, attr); tw = container_of(kobj, struct ufstw_lu, kobj); if (!entry->store) return -EIO; ufstw_lu_get(tw); mutex_lock(&tw->sysfs_lock); error = entry->store(tw, page, length); mutex_unlock(&tw->sysfs_lock); ufstw_lu_put(tw); return error; } static const struct sysfs_ops ufstw_sysfs_ops = { .show = ufstw_attr_show, .store = ufstw_attr_store, }; static struct kobj_type ufstw_ktype = { .sysfs_ops = &ufstw_sysfs_ops, .release = NULL, }; static int ufstw_create_sysfs(struct ufsf_feature *ufsf, struct ufstw_lu *tw) { struct device *dev = ufsf->hba->dev; struct ufstw_sysfs_entry *entry; int err; ufstw_lu_get(tw); tw->sysfs_entries = ufstw_sysfs_entries; kobject_init(&tw->kobj, &ufstw_ktype); mutex_init(&tw->sysfs_lock); INIT_INFO("ufstw creates sysfs ufstw_lu(%d) %p dev->kobj %p", tw->lun, &tw->kobj, &dev->kobj); err = kobject_add(&tw->kobj, kobject_get(&dev->kobj), "ufstw_lu%d", tw->lun); if (!err) { for (entry = tw->sysfs_entries; entry->attr.name != NULL; entry++) { INIT_INFO("ufstw_lu%d sysfs attr creates: %s", tw->lun, entry->attr.name); if (sysfs_create_file(&tw->kobj, &entry->attr)) break; } INIT_INFO("ufstw_lu%d sysfs adds uevent", tw->lun); kobject_uevent(&tw->kobj, KOBJ_ADD); } ufstw_lu_put(tw); return err; }