/* * Copyright (c) 2012-2019 The Linux Foundation. All rights reserved. * * Permission to use, copy, modify, and/or distribute this software for * any purpose with or without fee is hereby granted, provided that the * above copyright notice and this permission notice appear in all * copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL * WARRANTIES WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE * AUTHOR BE LIABLE FOR ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL * DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR * PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER * TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR * PERFORMANCE OF THIS SOFTWARE. */ /** * DOC: wifi_pos_main.c * This file defines the important functions pertinent to * wifi positioning to initialize and de-initialize the component. */ #include "target_if_wifi_pos.h" #include "wifi_pos_oem_interface_i.h" #include "wifi_pos_utils_i.h" #include "wifi_pos_api.h" #include "wifi_pos_main_i.h" #include "wifi_pos_ucfg_i.h" #include "wlan_objmgr_cmn.h" #include "wlan_objmgr_global_obj.h" #include "wlan_objmgr_psoc_obj.h" #include "wlan_objmgr_pdev_obj.h" #include "wlan_objmgr_vdev_obj.h" #include "wlan_ptt_sock_svc.h" #include "wlan_reg_services_api.h" /* forward declartion */ struct regulatory_channel; #define REG_SET_CHANNEL_REG_POWER(reg_info_1, val) do { \ reg_info_1 &= 0xff00ffff; \ reg_info_1 |= ((val & 0xff) << 16); \ } while (0) /* max tx power is in 1 dBm units */ #define REG_SET_CHANNEL_MAX_TX_POWER(reg_info_2, val) do { \ reg_info_2 &= 0xffff00ff; \ reg_info_2 |= ((val & 0xff) << 8); \ } while (0) /* channel info consists of 6 bits of channel mode */ #define REG_SET_CHANNEL_MODE(reg_channel, val) do { \ (reg_channel)->info &= 0xffffffc0; \ (reg_channel)->info |= (val); \ } while (0) /* * obj mgr api to iterate over vdevs does not provide a direct array or vdevs, * rather takes a callback that is called for every vdev. wifi pos needs to * store device mode and vdev id of all active vdevs and provide this info to * user space as part of APP registration response. due to this, vdev_idx is * used to identify how many vdevs have been populated by obj manager API. */ static uint32_t vdev_idx; /** * wifi_pos_get_tlv_support: indicates if firmware supports TLV wifi pos msg * @psoc: psoc object * * Return: status of operation */ static bool wifi_pos_get_tlv_support(struct wlan_objmgr_psoc *psoc) { /* this is TBD */ return true; } struct wlan_lmac_if_wifi_pos_tx_ops * wifi_pos_get_tx_ops(struct wlan_objmgr_psoc *psoc) { if (!psoc) { wifi_pos_err("psoc is null"); return NULL; } return &psoc->soc_cb.tx_ops.wifi_pos_tx_ops; } static QDF_STATUS wifi_pos_process_data_req(struct wlan_objmgr_psoc *psoc, struct wifi_pos_req_msg *req) { uint8_t idx; uint32_t sub_type = 0; uint32_t channel_mhz = 0; uint32_t pdev_id = 0; uint32_t offset; struct oem_data_req data_req; struct wlan_lmac_if_wifi_pos_tx_ops *tx_ops; struct wlan_objmgr_pdev *pdev; struct wifi_pos_psoc_priv_obj *wifi_pos_obj = wifi_pos_get_psoc_priv_obj(psoc); if (!wifi_pos_obj) { wifi_pos_err("wifi_pos priv obj is null"); return QDF_STATUS_E_INVAL; } wifi_pos_debug("Received data req pid(%d), len(%d)", req->pid, req->buf_len); /* look for fields */ if (req->field_info_buf) for (idx = 0; idx < req->field_info_buf->count; idx++) { offset = req->field_info_buf->fields[idx].offset; /* * replace following reads with read_api based on * length */ if (req->field_info_buf->fields[idx].id == WMIRTT_FIELD_ID_oem_data_sub_type) { sub_type = *((uint32_t *)&req->buf[offset]); continue; } if (req->field_info_buf->fields[idx].id == WMIRTT_FIELD_ID_channel_mhz) { channel_mhz = *((uint32_t *)&req->buf[offset]); continue; } if (req->field_info_buf->fields[idx].id == WMIRTT_FIELD_ID_pdev) { pdev_id = *((uint32_t *)&req->buf[offset]); /* pdev_id in FW starts from 1. So convert it to * host id by decrementing it. * zero has special meaning due to backward * compatibility. Dont change it. */ if (pdev_id) pdev_id -= 1; continue; } } switch (sub_type) { case TARGET_OEM_CAPABILITY_REQ: /* TBD */ break; case TARGET_OEM_CONFIGURE_LCR: /* TBD */ break; case TARGET_OEM_CONFIGURE_LCI: /* TBD */ break; case TARGET_OEM_MEASUREMENT_REQ: /* TBD */ break; case TARGET_OEM_CONFIGURE_FTMRR: wifi_pos_debug("FTMRR request"); if (wifi_pos_obj->wifi_pos_send_action) wifi_pos_obj->wifi_pos_send_action(psoc, sub_type, req->buf, req->buf_len); break; case TARGET_OEM_CONFIGURE_WRU: wifi_pos_debug("WRU request"); if (wifi_pos_obj->wifi_pos_send_action) wifi_pos_obj->wifi_pos_send_action(psoc, sub_type, req->buf, req->buf_len); break; default: wifi_pos_debug("invalid sub type or not passed"); tx_ops = wifi_pos_get_tx_ops(psoc); if (!tx_ops) { wifi_pos_err("tx ops null"); return QDF_STATUS_E_INVAL; } pdev = wlan_objmgr_get_pdev_by_id(psoc, pdev_id, WLAN_WIFI_POS_CORE_ID); if (pdev) { data_req.data_len = req->buf_len; data_req.data = req->buf; tx_ops->data_req_tx(pdev, &data_req); wlan_objmgr_pdev_release_ref(pdev, WLAN_WIFI_POS_CORE_ID); } break; } return QDF_STATUS_SUCCESS; } static QDF_STATUS wifi_pos_process_set_cap_req(struct wlan_objmgr_psoc *psoc, struct wifi_pos_req_msg *req) { int error_code; struct wifi_pos_psoc_priv_obj *wifi_pos_obj = wifi_pos_get_psoc_priv_obj(psoc); struct wifi_pos_user_defined_caps *caps = (struct wifi_pos_user_defined_caps *)req->buf; if (!wifi_pos_obj) { wifi_pos_err("wifi_pos priv obj is null"); return QDF_STATUS_E_INVAL; } wifi_pos_debug("Received set cap req pid(%d), len(%d)", req->pid, req->buf_len); wifi_pos_obj->ftm_rr = caps->ftm_rr; wifi_pos_obj->lci_capability = caps->lci_capability; error_code = qdf_status_to_os_return(QDF_STATUS_SUCCESS); wifi_pos_obj->wifi_pos_send_rsp(wifi_pos_obj->app_pid, ANI_MSG_SET_OEM_CAP_RSP, sizeof(error_code), (uint8_t *)&error_code); return QDF_STATUS_SUCCESS; } static QDF_STATUS wifi_pos_process_get_cap_req(struct wlan_objmgr_psoc *psoc, struct wifi_pos_req_msg *req) { struct wifi_pos_oem_get_cap_rsp cap_rsp = { { {0} } }; struct wifi_pos_psoc_priv_obj *wifi_pos_obj = wifi_pos_get_psoc_priv_obj(psoc); if (!wifi_pos_obj) { wifi_pos_err("wifi_pos priv obj is null"); return QDF_STATUS_E_INVAL; } wifi_pos_debug("Received get cap req pid(%d), len(%d)", req->pid, req->buf_len); wifi_pos_populate_caps(psoc, &cap_rsp.driver_cap); cap_rsp.user_defined_cap.ftm_rr = wifi_pos_obj->ftm_rr; cap_rsp.user_defined_cap.lci_capability = wifi_pos_obj->lci_capability; wifi_pos_obj->wifi_pos_send_rsp(wifi_pos_obj->app_pid, ANI_MSG_GET_OEM_CAP_RSP, sizeof(cap_rsp), (uint8_t *)&cap_rsp); return QDF_STATUS_SUCCESS; } QDF_STATUS wifi_pos_send_report_resp(struct wlan_objmgr_psoc *psoc, int req_id, uint8_t *dest_mac, int err_code) { struct wifi_pos_err_msg_report err_report = {0}; struct wifi_pos_psoc_priv_obj *wifi_pos_obj = wifi_pos_get_psoc_priv_obj(psoc); if (!wifi_pos_obj) { wifi_pos_err("wifi_pos priv obj is null"); return QDF_STATUS_E_INVAL; } err_report.msg_tag_len = OEM_MSG_RSP_HEAD_TAG_ID << 16; err_report.msg_tag_len |= (sizeof(err_report) - sizeof(err_report.err_rpt)) & 0x0000FFFF; err_report.msg_subtype = TARGET_OEM_ERROR_REPORT_RSP; err_report.req_id = req_id & 0xFFFF; err_report.req_id |= ((err_code & 0xFF) << 16); err_report.req_id |= (0x1 << 24); err_report.time_left = 0xFFFFFFFF; err_report.err_rpt.tag_len = OEM_MEAS_RSP_HEAD_TAG_ID << 16; err_report.err_rpt.tag_len |= (sizeof(struct wifi_pos_err_rpt)) & 0x0000FFFF; memcpy(&err_report.err_rpt.dest_mac, dest_mac, QDF_MAC_ADDR_SIZE); wifi_pos_obj->wifi_pos_send_rsp(wifi_pos_obj->app_pid, ANI_MSG_OEM_DATA_RSP, sizeof(err_report), (uint8_t *)&err_report); return QDF_STATUS_SUCCESS; } static void wifi_update_channel_bw_info(struct wlan_objmgr_psoc *psoc, struct wlan_objmgr_pdev *pdev, uint16_t chan, struct wifi_pos_ch_info_rsp *chan_info) { struct ch_params ch_params = {0}; uint16_t sec_ch_2g = 0; struct wifi_pos_psoc_priv_obj *wifi_pos_psoc = wifi_pos_get_psoc_priv_obj(psoc); uint32_t phy_mode; if (!wifi_pos_psoc) { wifi_pos_err("wifi_pos priv obj is null"); return; } /* Passing CH_WIDTH_MAX will give the max bandwidth supported */ ch_params.ch_width = CH_WIDTH_MAX; wlan_reg_set_channel_params(pdev, chan, sec_ch_2g, &ch_params); if (ch_params.center_freq_seg0) chan_info->band_center_freq1 = wlan_reg_legacy_chan_to_freq( pdev, ch_params.center_freq_seg0); wifi_pos_psoc->wifi_pos_get_phy_mode(chan, ch_params.ch_width, &phy_mode); REG_SET_CHANNEL_MODE(chan_info, phy_mode); } static void wifi_pos_get_reg_info(struct wlan_objmgr_pdev *pdev, uint32_t chan_num, uint32_t *reg_info_1, uint32_t *reg_info_2) { uint32_t reg_power = wlan_reg_get_channel_reg_power(pdev, chan_num); *reg_info_1 = 0; *reg_info_2 = 0; REG_SET_CHANNEL_REG_POWER(*reg_info_1, reg_power); REG_SET_CHANNEL_MAX_TX_POWER(*reg_info_2, reg_power); } /** * wifi_pos_get_valid_channels: Get the list of valid channels from the * given channel list * @channels: Channel list to be validated * @num_ch: NUmber of channels in the channel list to be validated * @valid_channel_list: Pointer to valid channel list * * Return: Number of valid channels in the given list */ static uint32_t wifi_pos_get_valid_channels(uint8_t *channels, uint32_t num_ch, uint8_t *valid_channel_list) { uint32_t i, num_valid_channels = 0; for (i = 0; i < num_ch; i++) { if (wlan_reg_get_chan_enum(channels[i]) == INVALID_CHANNEL) continue; valid_channel_list[num_valid_channels++] = channels[i]; } return num_valid_channels; } static QDF_STATUS wifi_pos_process_ch_info_req(struct wlan_objmgr_psoc *psoc, struct wifi_pos_req_msg *req) { uint8_t idx; uint8_t *buf; uint32_t len; uint32_t reg_info_1; uint32_t reg_info_2; uint8_t *channels = req->buf; struct wlan_objmgr_pdev *pdev; uint32_t num_ch = req->buf_len; uint8_t valid_channel_list[NUM_CHANNELS]; uint32_t num_valid_channels; struct wifi_pos_ch_info_rsp *ch_info; struct wifi_pos_psoc_priv_obj *wifi_pos_obj = wifi_pos_get_psoc_priv_obj(psoc); if (!wifi_pos_obj) { wifi_pos_err("wifi_pos priv obj is null"); return QDF_STATUS_E_INVAL; } wifi_pos_debug("Received ch info req pid(%d), len(%d)", req->pid, req->buf_len); /* get first pdev since we need that only for freq and dfs state */ pdev = wlan_objmgr_get_pdev_by_id(psoc, 0, WLAN_WIFI_POS_CORE_ID); if (!pdev) { wifi_pos_err("pdev get API failed"); return QDF_STATUS_E_INVAL; } if (num_ch > NUM_CHANNELS) { wifi_pos_err("Invalid number of channels"); return QDF_STATUS_E_INVAL; } num_valid_channels = wifi_pos_get_valid_channels(channels, num_ch, valid_channel_list); len = sizeof(uint8_t) + sizeof(struct wifi_pos_ch_info_rsp) * num_valid_channels; buf = qdf_mem_malloc(len); if (!buf) { wlan_objmgr_pdev_release_ref(pdev, WLAN_WIFI_POS_CORE_ID); return QDF_STATUS_E_NOMEM; } qdf_mem_zero(buf, len); /* First byte of message body will have num of channels */ buf[0] = num_valid_channels; ch_info = (struct wifi_pos_ch_info_rsp *)&buf[1]; for (idx = 0; idx < num_valid_channels; idx++) { ch_info[idx].chan_id = valid_channel_list[idx]; wifi_pos_get_reg_info(pdev, ch_info[idx].chan_id, ®_info_1, ®_info_2); ch_info[idx].reserved0 = 0; ch_info[idx].mhz = wlan_reg_get_channel_freq( pdev, valid_channel_list[idx]); ch_info[idx].band_center_freq1 = ch_info[idx].mhz; ch_info[idx].band_center_freq2 = 0; ch_info[idx].info = 0; if (wlan_reg_is_dfs_ch(pdev, valid_channel_list[idx])) WIFI_POS_SET_DFS(ch_info[idx].info); wifi_update_channel_bw_info(psoc, pdev, ch_info[idx].chan_id, &ch_info[idx]); ch_info[idx].reg_info_1 = reg_info_1; ch_info[idx].reg_info_2 = reg_info_2; } wifi_pos_obj->wifi_pos_send_rsp(wifi_pos_obj->app_pid, ANI_MSG_CHANNEL_INFO_RSP, len, buf); qdf_mem_free(buf); wlan_objmgr_pdev_release_ref(pdev, WLAN_WIFI_POS_CORE_ID); return QDF_STATUS_SUCCESS; } static void wifi_pos_vdev_iterator(struct wlan_objmgr_psoc *psoc, void *vdev, void *arg) { struct app_reg_rsp_vdev_info *vdev_info = arg; vdev_info[vdev_idx].dev_mode = wlan_vdev_mlme_get_opmode(vdev); vdev_info[vdev_idx].vdev_id = wlan_vdev_get_id(vdev); vdev_idx++; } static QDF_STATUS wifi_pos_process_app_reg_req(struct wlan_objmgr_psoc *psoc, struct wifi_pos_req_msg *req) { QDF_STATUS ret = QDF_STATUS_SUCCESS; uint8_t err = 0; uint32_t rsp_len; char *sign_str = NULL; struct wifi_app_reg_rsp *app_reg_rsp; struct app_reg_rsp_vdev_info vdevs_info[WLAN_UMAC_PSOC_MAX_VDEVS] = { { 0 } }; struct wifi_pos_psoc_priv_obj *wifi_pos_obj = wifi_pos_get_psoc_priv_obj(psoc); if (!wifi_pos_obj) { wifi_pos_err("wifi_pos priv obj is null"); return QDF_STATUS_E_INVAL; } wifi_pos_err("Received App Req Req pid(%d), len(%d)", req->pid, req->buf_len); sign_str = (char *)req->buf; /* Registration request is only allowed for QTI Application */ if ((OEM_APP_SIGNATURE_LEN != req->buf_len) || (strncmp(sign_str, OEM_APP_SIGNATURE_STR, OEM_APP_SIGNATURE_LEN))) { wifi_pos_err("Invalid signature pid(%d)", req->pid); ret = QDF_STATUS_E_PERM; err = OEM_ERR_INVALID_SIGNATURE; goto app_reg_failed; } wifi_pos_debug("Valid App Req Req from pid(%d)", req->pid); qdf_spin_lock_bh(&wifi_pos_obj->wifi_pos_lock); wifi_pos_obj->is_app_registered = true; wifi_pos_obj->app_pid = req->pid; qdf_spin_unlock_bh(&wifi_pos_obj->wifi_pos_lock); vdev_idx = 0; wlan_objmgr_iterate_obj_list(psoc, WLAN_VDEV_OP, wifi_pos_vdev_iterator, vdevs_info, true, WLAN_WIFI_POS_CORE_ID); rsp_len = (sizeof(struct app_reg_rsp_vdev_info) * vdev_idx) + sizeof(uint8_t); app_reg_rsp = qdf_mem_malloc(rsp_len); if (!app_reg_rsp) { ret = QDF_STATUS_E_NOMEM; err = OEM_ERR_NULL_CONTEXT; goto app_reg_failed; } app_reg_rsp->num_inf = vdev_idx; qdf_mem_copy(&app_reg_rsp->vdevs, vdevs_info, sizeof(struct app_reg_rsp_vdev_info) * vdev_idx); if (!vdev_idx) wifi_pos_debug("no active vdev"); vdev_idx = 0; wifi_pos_obj->wifi_pos_send_rsp(req->pid, ANI_MSG_APP_REG_RSP, rsp_len, (uint8_t *)app_reg_rsp); qdf_mem_free(app_reg_rsp); return ret; app_reg_failed: wifi_pos_obj->wifi_pos_send_rsp(req->pid, ANI_MSG_OEM_ERROR, sizeof(err), &err); return ret; } /** * wifi_pos_tlv_callback: wifi pos msg handler registered for TLV type req * @wmi_msg: wmi type request msg * * Return: status of operation */ static QDF_STATUS wifi_pos_tlv_callback(struct wlan_objmgr_psoc *psoc, struct wifi_pos_req_msg *req) { wifi_pos_debug("enter: msg_type: %d", req->msg_type); switch (req->msg_type) { case ANI_MSG_APP_REG_REQ: return wifi_pos_process_app_reg_req(psoc, req); case ANI_MSG_OEM_DATA_REQ: return wifi_pos_process_data_req(psoc, req); case ANI_MSG_CHANNEL_INFO_REQ: return wifi_pos_process_ch_info_req(psoc, req); case ANI_MSG_SET_OEM_CAP_REQ: return wifi_pos_process_set_cap_req(psoc, req); case ANI_MSG_GET_OEM_CAP_REQ: return wifi_pos_process_get_cap_req(psoc, req); default: wifi_pos_err("invalid request type"); break; } return 0; } /** * wifi_pos_non_tlv_callback: wifi pos msg handler registered for non-TLV * type req * @wmi_msg: wmi type request msg * * Return: status of operation */ static QDF_STATUS wifi_pos_non_tlv_callback(struct wlan_objmgr_psoc *psoc, struct wifi_pos_req_msg *req) { return QDF_STATUS_SUCCESS; } QDF_STATUS wifi_pos_psoc_obj_created_notification( struct wlan_objmgr_psoc *psoc, void *arg_list) { QDF_STATUS status; struct wifi_pos_psoc_priv_obj *wifi_pos_obj; /* * this is for WIN, if they have multiple psoc, we dont want to create * multiple priv object. Since there is just one LOWI app registered to * one driver, avoid 2nd private object with another psoc. */ if (wifi_pos_get_psoc()) { wifi_pos_debug("global psoc obj already set. do not allocate another psoc private object"); return QDF_STATUS_SUCCESS; } else { wifi_pos_debug("setting global pos object"); wifi_pos_set_psoc(psoc); } /* initialize wifi-pos psoc priv object */ wifi_pos_obj = qdf_mem_malloc(sizeof(*wifi_pos_obj)); if (!wifi_pos_obj) { wifi_pos_clear_psoc(); return QDF_STATUS_E_NOMEM; } qdf_spinlock_create(&wifi_pos_obj->wifi_pos_lock); /* Register TLV or non-TLV callbacks depending on target fw version */ if (wifi_pos_get_tlv_support(psoc)) wifi_pos_obj->wifi_pos_req_handler = wifi_pos_tlv_callback; else wifi_pos_obj->wifi_pos_req_handler = wifi_pos_non_tlv_callback; /* * MGMT Rx is not handled in this phase since wifi pos only uses few * measurement subtypes under RRM_RADIO_MEASURE_REQ. Rest of them are * used for 80211k. That part is not yet converged and still follows * legacy MGMT Rx to work. Action frame in new TXRX can be registered * at per ACTION Frame type granularity only. */ status = wlan_objmgr_psoc_component_obj_attach(psoc, WLAN_UMAC_COMP_WIFI_POS, wifi_pos_obj, QDF_STATUS_SUCCESS); if (QDF_IS_STATUS_ERROR(status)) { wifi_pos_err("obj attach with psoc failed with status: %d", status); qdf_spinlock_destroy(&wifi_pos_obj->wifi_pos_lock); qdf_mem_free(wifi_pos_obj); wifi_pos_clear_psoc(); } return status; } QDF_STATUS wifi_pos_psoc_obj_destroyed_notification( struct wlan_objmgr_psoc *psoc, void *arg_list) { QDF_STATUS status; struct wifi_pos_psoc_priv_obj *wifi_pos_obj = NULL; if (wifi_pos_get_psoc() == psoc) { wifi_pos_debug("deregistering wifi_pos_psoc object"); wifi_pos_clear_psoc(); } else { wifi_pos_warn("un-related PSOC closed. do nothing"); return QDF_STATUS_SUCCESS; } wifi_pos_obj = wifi_pos_get_psoc_priv_obj(psoc); if (!wifi_pos_obj) { wifi_pos_err("wifi_pos_obj is NULL"); return QDF_STATUS_E_FAULT; } target_if_wifi_pos_deinit_dma_rings(psoc); status = wlan_objmgr_psoc_component_obj_detach(psoc, WLAN_UMAC_COMP_WIFI_POS, wifi_pos_obj); if (status != QDF_STATUS_SUCCESS) wifi_pos_err("wifi_pos_obj detach failed"); wifi_pos_debug("wifi_pos_obj deleted with status %d", status); qdf_spinlock_destroy(&wifi_pos_obj->wifi_pos_lock); qdf_mem_free(wifi_pos_obj); return status; } int wifi_pos_oem_rsp_handler(struct wlan_objmgr_psoc *psoc, struct oem_data_rsp *oem_rsp) { uint32_t len; uint8_t *data; uint32_t app_pid; struct wifi_pos_psoc_priv_obj *priv = wifi_pos_get_psoc_priv_obj(psoc); void (*wifi_pos_send_rsp)(uint32_t, uint32_t, uint32_t, uint8_t *); if (!priv) { wifi_pos_err("private object is NULL"); return -EINVAL; } qdf_spin_lock_bh(&priv->wifi_pos_lock); app_pid = priv->app_pid; wifi_pos_send_rsp = priv->wifi_pos_send_rsp; qdf_spin_unlock_bh(&priv->wifi_pos_lock); len = oem_rsp->rsp_len_1 + oem_rsp->rsp_len_2 + oem_rsp->dma_len; if (oem_rsp->rsp_len_1 > OEM_DATA_RSP_SIZE || oem_rsp->rsp_len_2 > OEM_DATA_RSP_SIZE) { wifi_pos_err("invalid length of Oem Data response"); return -EINVAL; } if (!wifi_pos_send_rsp) { wifi_pos_err("invalid response handler"); return -EINVAL; } wifi_pos_debug("oem data rsp, len: %d to pid: %d", len, app_pid); if (oem_rsp->rsp_len_2 + oem_rsp->dma_len) { /* stitch togther the msg data_1 + CIR/CFR + data_2 */ data = qdf_mem_malloc(len); if (!data) return -ENOMEM; qdf_mem_copy(data, oem_rsp->data_1, oem_rsp->rsp_len_1); qdf_mem_copy(&data[oem_rsp->rsp_len_1], oem_rsp->vaddr, oem_rsp->dma_len); qdf_mem_copy(&data[oem_rsp->rsp_len_1 + oem_rsp->dma_len], oem_rsp->data_2, oem_rsp->rsp_len_2); wifi_pos_send_rsp(app_pid, ANI_MSG_OEM_DATA_RSP, len, data); qdf_mem_free(data); } else { wifi_pos_send_rsp(app_pid, ANI_MSG_OEM_DATA_RSP, oem_rsp->rsp_len_1, oem_rsp->data_1); } return 0; } void wifi_pos_register_rx_ops(struct wlan_lmac_if_rx_ops *rx_ops) { struct wlan_lmac_if_wifi_pos_rx_ops *wifi_pos_rx_ops; wifi_pos_rx_ops = &rx_ops->wifi_pos_rx_ops; wifi_pos_rx_ops->oem_rsp_event_rx = wifi_pos_oem_rsp_handler; } static void wifi_pos_pdev_iterator(struct wlan_objmgr_psoc *psoc, void *obj, void *arg) { QDF_STATUS status; uint8_t i, num_channels, size; struct wlan_objmgr_pdev *pdev = obj; struct wifi_pos_driver_caps *caps = arg; struct channel_power *ch_list; size = QDF_MAX(OEM_CAP_MAX_NUM_CHANNELS, NUM_CHANNELS); ch_list = qdf_mem_malloc(size * sizeof(*ch_list)); if (!ch_list) return; status = wlan_reg_get_channel_list_with_power(pdev, ch_list, &num_channels); if (QDF_IS_STATUS_ERROR(status)) { wifi_pos_err("Failed to get valid channel list"); qdf_mem_free(ch_list); return; } if (num_channels > OEM_CAP_MAX_NUM_CHANNELS) num_channels = OEM_CAP_MAX_NUM_CHANNELS; for (i = 0; i < num_channels; i++) caps->channel_list[i] = ch_list[i].chan_num; caps->num_channels = num_channels; qdf_mem_free(ch_list); } static void wifi_pos_get_ch_info(struct wlan_objmgr_psoc *psoc, struct wifi_pos_driver_caps *caps) { wlan_objmgr_iterate_obj_list(psoc, WLAN_PDEV_OP, wifi_pos_pdev_iterator, caps, true, WLAN_WIFI_POS_CORE_ID); wifi_pos_err("num channels: %d", caps->num_channels); } QDF_STATUS wifi_pos_populate_caps(struct wlan_objmgr_psoc *psoc, struct wifi_pos_driver_caps *caps) { struct wifi_pos_psoc_priv_obj *wifi_pos_obj = wifi_pos_get_psoc_priv_obj(psoc); wifi_pos_debug("Enter"); if (!wifi_pos_obj) { wifi_pos_err("wifi_pos_obj is null"); return QDF_STATUS_E_NULL_VALUE; } strlcpy(caps->oem_target_signature, OEM_TARGET_SIGNATURE, OEM_TARGET_SIGNATURE_LEN); caps->oem_target_type = wifi_pos_obj->oem_target_type; caps->oem_fw_version = wifi_pos_obj->oem_fw_version; caps->driver_version.major = wifi_pos_obj->driver_version.major; caps->driver_version.minor = wifi_pos_obj->driver_version.minor; caps->driver_version.patch = wifi_pos_obj->driver_version.patch; caps->driver_version.build = wifi_pos_obj->driver_version.build; caps->allowed_dwell_time_min = wifi_pos_obj->allowed_dwell_time_min; caps->allowed_dwell_time_max = wifi_pos_obj->allowed_dwell_time_max; caps->curr_dwell_time_min = wifi_pos_obj->current_dwell_time_min; caps->curr_dwell_time_max = wifi_pos_obj->current_dwell_time_max; caps->supported_bands = wlan_objmgr_psoc_get_band_capability(psoc); wifi_pos_get_ch_info(psoc, caps); return QDF_STATUS_SUCCESS; }