/* * * Copyright (c) 2004-2010 Atheros Communications Inc. * All rights reserved. * * // This program is free software; you can redistribute it and/or modify // it under the terms of the GNU General Public License version 2 as // published by the Free Software Foundation; // // Software distributed under the License is distributed on an "AS // IS" basis, WITHOUT WARRANTY OF ANY KIND, either express or // implied. See the License for the specific language governing // rights and limitations under the License. // // * */ #include "ar6000_drv.h" #include "ieee80211_ioctl.h" #include "ar6kap_common.h" #include "targaddrs.h" #include "a_hci.h" #include "wlan_config.h" extern int enablerssicompensation; A_UINT32 tcmdRxFreq; extern unsigned int wmitimeout; extern A_WAITQUEUE_HEAD arEvent; extern int tspecCompliance; extern int bmienable; extern int bypasswmi; extern int loghci; static int ar6000_ioctl_get_roam_tbl(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); if (ar->arWmiReady == FALSE) { return -EIO; } if(wmi_get_roam_tbl_cmd(ar->arWmi) != A_OK) { return -EIO; } return 0; } static int ar6000_ioctl_get_roam_data(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); if (ar->arWmiReady == FALSE) { return -EIO; } /* currently assume only roam times are required */ if(wmi_get_roam_data_cmd(ar->arWmi, ROAM_DATA_TIME) != A_OK) { return -EIO; } return 0; } static int ar6000_ioctl_set_roam_ctrl(struct net_device *dev, char *userdata) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_ROAM_CTRL_CMD cmd; A_UINT8 size = sizeof(cmd); if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, userdata, size)) { return -EFAULT; } if (cmd.roamCtrlType == WMI_SET_HOST_BIAS) { if (cmd.info.bssBiasInfo.numBss > 1) { size += (cmd.info.bssBiasInfo.numBss - 1) * sizeof(WMI_BSS_BIAS); } } if (copy_from_user(&cmd, userdata, size)) { return -EFAULT; } if(wmi_set_roam_ctrl_cmd(ar->arWmi, &cmd, size) != A_OK) { return -EIO; } return 0; } static int ar6000_ioctl_set_powersave_timers(struct net_device *dev, char *userdata) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_POWERSAVE_TIMERS_POLICY_CMD cmd; A_UINT8 size = sizeof(cmd); if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, userdata, size)) { return -EFAULT; } if (copy_from_user(&cmd, userdata, size)) { return -EFAULT; } if(wmi_set_powersave_timers_cmd(ar->arWmi, &cmd, size) != A_OK) { return -EIO; } return 0; } static int ar6000_ioctl_set_qos_supp(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_QOS_SUPP_CMD cmd; A_STATUS ret; if ((dev->flags & IFF_UP) != IFF_UP) { return -EIO; } if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, (char *)((unsigned int*)rq->ifr_data + 1), sizeof(cmd))) { return -EFAULT; } ret = wmi_set_qos_supp_cmd(ar->arWmi, cmd.status); switch (ret) { case A_OK: return 0; case A_EBUSY : return -EBUSY; case A_NO_MEMORY: return -ENOMEM; case A_EINVAL: default: return -EFAULT; } } static int ar6000_ioctl_set_wmm(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_WMM_CMD cmd; A_STATUS ret; if ((dev->flags & IFF_UP) != IFF_UP) { return -EIO; } if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, (char *)((unsigned int*)rq->ifr_data + 1), sizeof(cmd))) { return -EFAULT; } if (cmd.status == WMI_WMM_ENABLED) { ar->arWmmEnabled = TRUE; } else { ar->arWmmEnabled = FALSE; } ret = wmi_set_wmm_cmd(ar->arWmi, cmd.status); switch (ret) { case A_OK: return 0; case A_EBUSY : return -EBUSY; case A_NO_MEMORY: return -ENOMEM; case A_EINVAL: default: return -EFAULT; } } static int ar6000_ioctl_set_txop(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_WMM_TXOP_CMD cmd; A_STATUS ret; if ((dev->flags & IFF_UP) != IFF_UP) { return -EIO; } if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, (char *)((unsigned int*)rq->ifr_data + 1), sizeof(cmd))) { return -EFAULT; } ret = wmi_set_wmm_txop(ar->arWmi, cmd.txopEnable); switch (ret) { case A_OK: return 0; case A_EBUSY : return -EBUSY; case A_NO_MEMORY: return -ENOMEM; case A_EINVAL: default: return -EFAULT; } } static int ar6000_ioctl_get_rd(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); A_STATUS ret = 0; if ((dev->flags & IFF_UP) != IFF_UP || ar->arWmiReady == FALSE) { return -EIO; } if(copy_to_user((char *)((unsigned int*)rq->ifr_data + 1), &ar->arRegCode, sizeof(ar->arRegCode))) ret = -EFAULT; return ret; } static int ar6000_ioctl_set_country(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_AP_SET_COUNTRY_CMD cmd; A_STATUS ret; if ((dev->flags & IFF_UP) != IFF_UP) { return -EIO; } if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, (char *)((unsigned int*)rq->ifr_data + 1), sizeof(cmd))) { return -EFAULT; } ar->ap_profile_flag = 1; /* There is a change in profile */ ret = wmi_set_country(ar->arWmi, cmd.countryCode); A_MEMCPY(ar->ap_country_code, cmd.countryCode, 3); switch (ret) { case A_OK: return 0; case A_EBUSY : return -EBUSY; case A_NO_MEMORY: return -ENOMEM; case A_EINVAL: default: return -EFAULT; } } /* Get power mode command */ static int ar6000_ioctl_get_power_mode(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_POWER_MODE_CMD power_mode; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } power_mode.powerMode = wmi_get_power_mode_cmd(ar->arWmi); if (copy_to_user(rq->ifr_data, &power_mode, sizeof(WMI_POWER_MODE_CMD))) { ret = -EFAULT; } return ret; } static int ar6000_ioctl_set_channelParams(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_CHANNEL_PARAMS_CMD cmd, *cmdp; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, rq->ifr_data, sizeof(cmd))) { return -EFAULT; } if( (ar->arNextMode == AP_NETWORK) && (cmd.numChannels || cmd.scanParam) ) { A_PRINTF("ERROR: Only wmode is allowed in AP mode\n"); return -EIO; } if (cmd.numChannels > 1) { cmdp = A_MALLOC(130); if (copy_from_user(cmdp, rq->ifr_data, sizeof (*cmdp) + ((cmd.numChannels - 1) * sizeof(A_UINT16)))) { kfree(cmdp); return -EFAULT; } } else { cmdp = &cmd; } if ((ar->arPhyCapability == WMI_11G_CAPABILITY) && ((cmdp->phyMode == WMI_11A_MODE) || (cmdp->phyMode == WMI_11AG_MODE))) { ret = -EINVAL; } if (!ret && (wmi_set_channelParams_cmd(ar->arWmi, cmdp->scanParam, cmdp->phyMode, cmdp->numChannels, cmdp->channelList) != A_OK)) { ret = -EIO; } if (cmd.numChannels > 1) { kfree(cmdp); } ar->ap_wmode = cmdp->phyMode; /* Set the profile change flag to allow a commit cmd */ ar->ap_profile_flag = 1; return ret; } static int ar6000_ioctl_set_snr_threshold(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SNR_THRESHOLD_PARAMS_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, rq->ifr_data, sizeof(cmd))) { return -EFAULT; } if( wmi_set_snr_threshold_params(ar->arWmi, &cmd) != A_OK ) { ret = -EIO; } return ret; } static int ar6000_ioctl_set_rssi_threshold(struct net_device *dev, struct ifreq *rq) { #define SWAP_THOLD(thold1, thold2) do { \ USER_RSSI_THOLD tmpThold; \ tmpThold.tag = thold1.tag; \ tmpThold.rssi = thold1.rssi; \ thold1.tag = thold2.tag; \ thold1.rssi = thold2.rssi; \ thold2.tag = tmpThold.tag; \ thold2.rssi = tmpThold.rssi; \ } while (0) AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_RSSI_THRESHOLD_PARAMS_CMD cmd; USER_RSSI_PARAMS rssiParams; A_INT32 i, j; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user((char *)&rssiParams, (char *)((unsigned int *)rq->ifr_data + 1), sizeof(USER_RSSI_PARAMS))) { return -EFAULT; } cmd.weight = rssiParams.weight; cmd.pollTime = rssiParams.pollTime; A_MEMCPY(ar->rssi_map, &rssiParams.tholds, sizeof(ar->rssi_map)); /* * only 6 elements, so use bubble sorting, in ascending order */ for (i = 5; i > 0; i--) { for (j = 0; j < i; j++) { /* above tholds */ if (ar->rssi_map[j+1].rssi < ar->rssi_map[j].rssi) { SWAP_THOLD(ar->rssi_map[j+1], ar->rssi_map[j]); } else if (ar->rssi_map[j+1].rssi == ar->rssi_map[j].rssi) { return EFAULT; } } } for (i = 11; i > 6; i--) { for (j = 6; j < i; j++) { /* below tholds */ if (ar->rssi_map[j+1].rssi < ar->rssi_map[j].rssi) { SWAP_THOLD(ar->rssi_map[j+1], ar->rssi_map[j]); } else if (ar->rssi_map[j+1].rssi == ar->rssi_map[j].rssi) { return EFAULT; } } } #ifdef DEBUG for (i = 0; i < 12; i++) { AR_DEBUG_PRINTF(ATH_DEBUG_INFO,("thold[%d].tag: %d, thold[%d].rssi: %d \n", i, ar->rssi_map[i].tag, i, ar->rssi_map[i].rssi)); } #endif if (enablerssicompensation) { for (i = 0; i < 6; i++) ar->rssi_map[i].rssi = rssi_compensation_reverse_calc(ar, ar->rssi_map[i].rssi, TRUE); for (i = 6; i < 12; i++) ar->rssi_map[i].rssi = rssi_compensation_reverse_calc(ar, ar->rssi_map[i].rssi, FALSE); } cmd.thresholdAbove1_Val = ar->rssi_map[0].rssi; cmd.thresholdAbove2_Val = ar->rssi_map[1].rssi; cmd.thresholdAbove3_Val = ar->rssi_map[2].rssi; cmd.thresholdAbove4_Val = ar->rssi_map[3].rssi; cmd.thresholdAbove5_Val = ar->rssi_map[4].rssi; cmd.thresholdAbove6_Val = ar->rssi_map[5].rssi; cmd.thresholdBelow1_Val = ar->rssi_map[6].rssi; cmd.thresholdBelow2_Val = ar->rssi_map[7].rssi; cmd.thresholdBelow3_Val = ar->rssi_map[8].rssi; cmd.thresholdBelow4_Val = ar->rssi_map[9].rssi; cmd.thresholdBelow5_Val = ar->rssi_map[10].rssi; cmd.thresholdBelow6_Val = ar->rssi_map[11].rssi; if( wmi_set_rssi_threshold_params(ar->arWmi, &cmd) != A_OK ) { ret = -EIO; } return ret; } static int ar6000_ioctl_set_lq_threshold(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_LQ_THRESHOLD_PARAMS_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, (char *)((unsigned int *)rq->ifr_data + 1), sizeof(cmd))) { return -EFAULT; } if( wmi_set_lq_threshold_params(ar->arWmi, &cmd) != A_OK ) { ret = -EIO; } return ret; } static int ar6000_ioctl_set_probedSsid(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_PROBED_SSID_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, rq->ifr_data, sizeof(cmd))) { return -EFAULT; } if (wmi_probedSsid_cmd(ar->arWmi, cmd.entryIndex, cmd.flag, cmd.ssidLength, cmd.ssid) != A_OK) { ret = -EIO; } return ret; } static int ar6000_ioctl_set_badAp(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_ADD_BAD_AP_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, rq->ifr_data, sizeof(cmd))) { return -EFAULT; } if (cmd.badApIndex > WMI_MAX_BAD_AP_INDEX) { return -EIO; } if (A_MEMCMP(cmd.bssid, null_mac, AR6000_ETH_ADDR_LEN) == 0) { /* * This is a delete badAP. */ if (wmi_deleteBadAp_cmd(ar->arWmi, cmd.badApIndex) != A_OK) { ret = -EIO; } } else { if (wmi_addBadAp_cmd(ar->arWmi, cmd.badApIndex, cmd.bssid) != A_OK) { ret = -EIO; } } return ret; } static int ar6000_ioctl_create_qos(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_CREATE_PSTREAM_CMD cmd; A_STATUS ret; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, rq->ifr_data, sizeof(cmd))) { return -EFAULT; } ret = wmi_verify_tspec_params(&cmd, tspecCompliance); if (ret == A_OK) ret = wmi_create_pstream_cmd(ar->arWmi, &cmd); switch (ret) { case A_OK: return 0; case A_EBUSY : return -EBUSY; case A_NO_MEMORY: return -ENOMEM; case A_EINVAL: default: return -EFAULT; } } static int ar6000_ioctl_delete_qos(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_DELETE_PSTREAM_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, rq->ifr_data, sizeof(cmd))) { return -EFAULT; } ret = wmi_delete_pstream_cmd(ar->arWmi, cmd.trafficClass, cmd.tsid); switch (ret) { case A_OK: return 0; case A_EBUSY : return -EBUSY; case A_NO_MEMORY: return -ENOMEM; case A_EINVAL: default: return -EFAULT; } } static int ar6000_ioctl_get_qos_queue(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); struct ar6000_queuereq qreq; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if( copy_from_user(&qreq, rq->ifr_data, sizeof(struct ar6000_queuereq))) return -EFAULT; qreq.activeTsids = wmi_get_mapped_qos_queue(ar->arWmi, qreq.trafficClass); if (copy_to_user(rq->ifr_data, &qreq, sizeof(struct ar6000_queuereq))) { ret = -EFAULT; } return ret; } #ifdef CONFIG_HOST_TCMD_SUPPORT static A_STATUS ar6000_ioctl_tcmd_get_rx_report(struct net_device *dev, struct ifreq *rq, A_UINT8 *data, A_UINT32 len) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); A_UINT32 buf[4+TCMD_MAX_RATES]; int ret = 0; if (ar->bIsDestroyProgress) { return -EBUSY; } if (ar->arWmiReady == FALSE) { return -EIO; } if (down_interruptible(&ar->arSem)) { return -ERESTARTSYS; } if (ar->bIsDestroyProgress) { up(&ar->arSem); return -EBUSY; } ar->tcmdRxReport = 0; if (wmi_test_cmd(ar->arWmi, data, len) != A_OK) { up(&ar->arSem); return -EIO; } wait_event_interruptible_timeout(arEvent, ar->tcmdRxReport != 0, wmitimeout * HZ); if (signal_pending(current)) { ret = -EINTR; } buf[0] = ar->tcmdRxTotalPkt; buf[1] = ar->tcmdRxRssi; buf[2] = ar->tcmdRxcrcErrPkt; buf[3] = ar->tcmdRxsecErrPkt; A_MEMCPY(((A_UCHAR *)buf)+(4*sizeof(A_UINT32)), ar->tcmdRateCnt, sizeof(ar->tcmdRateCnt)); A_MEMCPY(((A_UCHAR *)buf)+(4*sizeof(A_UINT32))+(TCMD_MAX_RATES *sizeof(A_UINT16)), ar->tcmdRateCntShortGuard, sizeof(ar->tcmdRateCntShortGuard)); if (!ret && copy_to_user(rq->ifr_data, buf, sizeof(buf))) { ret = -EFAULT; } up(&ar->arSem); return ret; } void ar6000_tcmd_rx_report_event(void *devt, A_UINT8 * results, int len) { AR_SOFTC_T *ar = (AR_SOFTC_T *)devt; TCMD_CONT_RX * rx_rep = (TCMD_CONT_RX *)results; if (enablerssicompensation) { rx_rep->u.report.rssiInDBm = rssi_compensation_calc_tcmd(tcmdRxFreq, rx_rep->u.report.rssiInDBm,rx_rep->u.report.totalPkt); } ar->tcmdRxTotalPkt = rx_rep->u.report.totalPkt; ar->tcmdRxRssi = rx_rep->u.report.rssiInDBm; ar->tcmdRxcrcErrPkt = rx_rep->u.report.crcErrPkt; ar->tcmdRxsecErrPkt = rx_rep->u.report.secErrPkt; ar->tcmdRxReport = 1; A_MEMZERO(ar->tcmdRateCnt, sizeof(ar->tcmdRateCnt)); A_MEMZERO(ar->tcmdRateCntShortGuard, sizeof(ar->tcmdRateCntShortGuard)); A_MEMCPY(ar->tcmdRateCnt, rx_rep->u.report.rateCnt, sizeof(ar->tcmdRateCnt)); A_MEMCPY(ar->tcmdRateCntShortGuard, rx_rep->u.report.rateCntShortGuard, sizeof(ar->tcmdRateCntShortGuard)); wake_up(&arEvent); } #endif /* CONFIG_HOST_TCMD_SUPPORT*/ static int ar6000_ioctl_set_error_report_bitmask(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_TARGET_ERROR_REPORT_BITMASK cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, rq->ifr_data, sizeof(cmd))) { return -EFAULT; } ret = wmi_set_error_report_bitmask(ar->arWmi, cmd.bitmask); return (ret==0 ? ret : -EINVAL); } static int ar6000_clear_target_stats(struct net_device *dev) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); TARGET_STATS *pStats = &ar->arTargetStats; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } AR6000_SPIN_LOCK(&ar->arLock, 0); A_MEMZERO(pStats, sizeof(TARGET_STATS)); AR6000_SPIN_UNLOCK(&ar->arLock, 0); return ret; } static int ar6000_ioctl_get_target_stats(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); TARGET_STATS_CMD cmd; TARGET_STATS *pStats = &ar->arTargetStats; int ret = 0; if (ar->bIsDestroyProgress) { return -EBUSY; } if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, rq->ifr_data, sizeof(cmd))) { return -EFAULT; } if (down_interruptible(&ar->arSem)) { return -ERESTARTSYS; } if (ar->bIsDestroyProgress) { up(&ar->arSem); return -EBUSY; } ar->statsUpdatePending = TRUE; if(wmi_get_stats_cmd(ar->arWmi) != A_OK) { up(&ar->arSem); return -EIO; } wait_event_interruptible_timeout(arEvent, ar->statsUpdatePending == FALSE, wmitimeout * HZ); if (signal_pending(current)) { ret = -EINTR; } if (!ret && copy_to_user(rq->ifr_data, pStats, sizeof(*pStats))) { ret = -EFAULT; } if (cmd.clearStats == 1) { ret = ar6000_clear_target_stats(dev); } up(&ar->arSem); return ret; } static int ar6000_ioctl_get_ap_stats(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_AP_MODE_STAT cmd; WMI_AP_MODE_STAT *pStats = &ar->arAPStats; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, (char *)((unsigned int*)rq->ifr_data + 1), sizeof(cmd))) { return -EFAULT; } if (cmd.action == AP_CLEAR_STATS) { A_UINT8 i; AR6000_SPIN_LOCK(&ar->arLock, 0); for(i = 0; i < AP_MAX_NUM_STA; i++) { pStats->sta[i].tx_bytes = 0; pStats->sta[i].tx_pkts = 0; pStats->sta[i].tx_error = 0; pStats->sta[i].tx_discard = 0; pStats->sta[i].rx_bytes = 0; pStats->sta[i].rx_pkts = 0; pStats->sta[i].rx_error = 0; pStats->sta[i].rx_discard = 0; } AR6000_SPIN_UNLOCK(&ar->arLock, 0); return ret; } if (down_interruptible(&ar->arSem)) { return -ERESTARTSYS; } ar->statsUpdatePending = TRUE; if(wmi_get_stats_cmd(ar->arWmi) != A_OK) { up(&ar->arSem); return -EIO; } wait_event_interruptible_timeout(arEvent, ar->statsUpdatePending == FALSE, wmitimeout * HZ); if (signal_pending(current)) { ret = -EINTR; } if (!ret && copy_to_user(rq->ifr_data, pStats, sizeof(*pStats))) { ret = -EFAULT; } up(&ar->arSem); return ret; } static int ar6000_ioctl_set_access_params(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_ACCESS_PARAMS_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, rq->ifr_data, sizeof(cmd))) { return -EFAULT; } if (wmi_set_access_params_cmd(ar->arWmi, cmd.ac, cmd.txop, cmd.eCWmin, cmd.eCWmax, cmd.aifsn) == A_OK) { ret = 0; } else { ret = -EINVAL; } return (ret); } static int ar6000_ioctl_set_disconnect_timeout(struct net_device *dev, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_DISC_TIMEOUT_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, rq->ifr_data, sizeof(cmd))) { return -EFAULT; } if (wmi_disctimeout_cmd(ar->arWmi, cmd.disconnectTimeout) == A_OK) { ret = 0; } else { ret = -EINVAL; } return (ret); } static int ar6000_xioctl_set_voice_pkt_size(struct net_device *dev, char * userdata) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_VOICE_PKT_SIZE_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, userdata, sizeof(cmd))) { return -EFAULT; } if (wmi_set_voice_pkt_size_cmd(ar->arWmi, cmd.voicePktSize) == A_OK) { ret = 0; } else { ret = -EINVAL; } return (ret); } static int ar6000_xioctl_set_max_sp_len(struct net_device *dev, char * userdata) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_MAX_SP_LEN_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, userdata, sizeof(cmd))) { return -EFAULT; } if (wmi_set_max_sp_len_cmd(ar->arWmi, cmd.maxSPLen) == A_OK) { ret = 0; } else { ret = -EINVAL; } return (ret); } static int ar6000_xioctl_set_bt_status_cmd(struct net_device *dev, char * userdata) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_BT_STATUS_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, userdata, sizeof(cmd))) { return -EFAULT; } if (wmi_set_bt_status_cmd(ar->arWmi, cmd.streamType, cmd.status) == A_OK) { ret = 0; } else { ret = -EINVAL; } return (ret); } static int ar6000_xioctl_set_bt_params_cmd(struct net_device *dev, char * userdata) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_BT_PARAMS_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, userdata, sizeof(cmd))) { return -EFAULT; } if (wmi_set_bt_params_cmd(ar->arWmi, &cmd) == A_OK) { ret = 0; } else { ret = -EINVAL; } return (ret); } static int ar6000_xioctl_set_btcoex_fe_ant_cmd(struct net_device * dev, char * userdata) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_BTCOEX_FE_ANT_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, userdata, sizeof(cmd))) { return -EFAULT; } if (wmi_set_btcoex_fe_ant_cmd(ar->arWmi, &cmd) == A_OK) { ret = 0; } else { ret = -EINVAL; } return(ret); } static int ar6000_xioctl_set_btcoex_colocated_bt_dev_cmd(struct net_device * dev, char * userdata) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_BTCOEX_COLOCATED_BT_DEV_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, userdata, sizeof(cmd))) { return -EFAULT; } if (wmi_set_btcoex_colocated_bt_dev_cmd(ar->arWmi, &cmd) == A_OK) { ret = 0; } else { ret = -EINVAL; } return(ret); } static int ar6000_xioctl_set_btcoex_btinquiry_page_config_cmd(struct net_device * dev, char * userdata) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_BTCOEX_BTINQUIRY_PAGE_CONFIG_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, userdata, sizeof(cmd))) { return -EFAULT; } if (wmi_set_btcoex_btinquiry_page_config_cmd(ar->arWmi, &cmd) == A_OK) { ret = 0; } else { ret = -EINVAL; } return(ret); } static int ar6000_xioctl_set_btcoex_sco_config_cmd(struct net_device * dev, char * userdata) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_BTCOEX_SCO_CONFIG_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, userdata, sizeof(cmd))) { return -EFAULT; } if (wmi_set_btcoex_sco_config_cmd(ar->arWmi, &cmd) == A_OK) { ret = 0; } else { ret = -EINVAL; } return(ret); } static int ar6000_xioctl_set_btcoex_a2dp_config_cmd(struct net_device * dev, char * userdata) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_BTCOEX_A2DP_CONFIG_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, userdata, sizeof(cmd))) { return -EFAULT; } if (wmi_set_btcoex_a2dp_config_cmd(ar->arWmi, &cmd) == A_OK) { ret = 0; } else { ret = -EINVAL; } return(ret); } static int ar6000_xioctl_set_btcoex_aclcoex_config_cmd(struct net_device * dev, char * userdata) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_BTCOEX_ACLCOEX_CONFIG_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, userdata, sizeof(cmd))) { return -EFAULT; } if (wmi_set_btcoex_aclcoex_config_cmd(ar->arWmi, &cmd) == A_OK) { ret = 0; } else { ret = -EINVAL; } return(ret); } static int ar60000_xioctl_set_btcoex_debug_cmd(struct net_device * dev, char * userdata) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_BTCOEX_DEBUG_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, userdata, sizeof(cmd))) { return -EFAULT; } if (wmi_set_btcoex_debug_cmd(ar->arWmi, &cmd) == A_OK) { ret = 0; } else { ret = -EINVAL; } return(ret); } static int ar6000_xioctl_set_btcoex_bt_operating_status_cmd(struct net_device * dev, char * userdata) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_SET_BTCOEX_BT_OPERATING_STATUS_CMD cmd; int ret = 0; if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&cmd, userdata, sizeof(cmd))) { return -EFAULT; } if (wmi_set_btcoex_bt_operating_status_cmd(ar->arWmi, &cmd) == A_OK) { ret = 0; } else { ret = -EINVAL; } return(ret); } static int ar6000_xioctl_get_btcoex_config_cmd(struct net_device * dev, char * userdata, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); AR6000_BTCOEX_CONFIG btcoexConfig; WMI_BTCOEX_CONFIG_EVENT *pbtcoexConfigEv = &ar->arBtcoexConfig; int ret = 0; if (ar->bIsDestroyProgress) { return -EBUSY; } if (ar->arWmiReady == FALSE) { return -EIO; } if (copy_from_user(&btcoexConfig.configCmd, userdata, sizeof(AR6000_BTCOEX_CONFIG))) { return -EFAULT; } if (down_interruptible(&ar->arSem)) { return -ERESTARTSYS; } if (wmi_get_btcoex_config_cmd(ar->arWmi, (WMI_GET_BTCOEX_CONFIG_CMD *)&btcoexConfig.configCmd) != A_OK) { up(&ar->arSem); return -EIO; } ar->statsUpdatePending = TRUE; wait_event_interruptible_timeout(arEvent, ar->statsUpdatePending == FALSE, wmitimeout * HZ); if (signal_pending(current)) { ret = -EINTR; } if (!ret && copy_to_user(btcoexConfig.configEvent, pbtcoexConfigEv, sizeof(WMI_BTCOEX_CONFIG_EVENT))) { ret = -EFAULT; } up(&ar->arSem); return ret; } static int ar6000_xioctl_get_btcoex_stats_cmd(struct net_device * dev, char * userdata, struct ifreq *rq) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); AR6000_BTCOEX_STATS btcoexStats; WMI_BTCOEX_STATS_EVENT *pbtcoexStats = &ar->arBtcoexStats; int ret = 0; if (ar->bIsDestroyProgress) { return -EBUSY; } if (ar->arWmiReady == FALSE) { return -EIO; } if (down_interruptible(&ar->arSem)) { return -ERESTARTSYS; } if (copy_from_user(&btcoexStats.statsEvent, userdata, sizeof(AR6000_BTCOEX_CONFIG))) { return -EFAULT; } if (wmi_get_btcoex_stats_cmd(ar->arWmi) != A_OK) { up(&ar->arSem); return -EIO; } ar->statsUpdatePending = TRUE; wait_event_interruptible_timeout(arEvent, ar->statsUpdatePending == FALSE, wmitimeout * HZ); if (signal_pending(current)) { ret = -EINTR; } if (!ret && copy_to_user(btcoexStats.statsEvent, pbtcoexStats, sizeof(WMI_BTCOEX_STATS_EVENT))) { ret = -EFAULT; } up(&ar->arSem); return(ret); } #ifdef CONFIG_HOST_GPIO_SUPPORT struct ar6000_gpio_intr_wait_cmd_s gpio_intr_results; /* gpio_reg_results and gpio_data_available are protected by arSem */ static struct ar6000_gpio_register_cmd_s gpio_reg_results; static A_BOOL gpio_data_available; /* Requested GPIO data available */ static A_BOOL gpio_intr_available; /* GPIO interrupt info available */ static A_BOOL gpio_ack_received; /* GPIO ack was received */ /* Host-side initialization for General Purpose I/O support */ void ar6000_gpio_init(void) { gpio_intr_available = FALSE; gpio_data_available = FALSE; gpio_ack_received = FALSE; } /* * Called when a GPIO interrupt is received from the Target. * intr_values shows which GPIO pins have interrupted. * input_values shows a recent value of GPIO pins. */ void ar6000_gpio_intr_rx(A_UINT32 intr_mask, A_UINT32 input_values) { gpio_intr_results.intr_mask = intr_mask; gpio_intr_results.input_values = input_values; *((volatile A_BOOL *)&gpio_intr_available) = TRUE; wake_up(&arEvent); } /* * This is called when a response is received from the Target * for a previous or ar6000_gpio_input_get or ar6000_gpio_register_get * call. */ void ar6000_gpio_data_rx(A_UINT32 reg_id, A_UINT32 value) { gpio_reg_results.gpioreg_id = reg_id; gpio_reg_results.value = value; *((volatile A_BOOL *)&gpio_data_available) = TRUE; wake_up(&arEvent); } /* * This is called when an acknowledgement is received from the Target * for a previous or ar6000_gpio_output_set or ar6000_gpio_register_set * call. */ void ar6000_gpio_ack_rx(void) { gpio_ack_received = TRUE; wake_up(&arEvent); } A_STATUS ar6000_gpio_output_set(struct net_device *dev, A_UINT32 set_mask, A_UINT32 clear_mask, A_UINT32 enable_mask, A_UINT32 disable_mask) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); gpio_ack_received = FALSE; return wmi_gpio_output_set(ar->arWmi, set_mask, clear_mask, enable_mask, disable_mask); } static A_STATUS ar6000_gpio_input_get(struct net_device *dev) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); *((volatile A_BOOL *)&gpio_data_available) = FALSE; return wmi_gpio_input_get(ar->arWmi); } static A_STATUS ar6000_gpio_register_set(struct net_device *dev, A_UINT32 gpioreg_id, A_UINT32 value) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); gpio_ack_received = FALSE; return wmi_gpio_register_set(ar->arWmi, gpioreg_id, value); } static A_STATUS ar6000_gpio_register_get(struct net_device *dev, A_UINT32 gpioreg_id) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); *((volatile A_BOOL *)&gpio_data_available) = FALSE; return wmi_gpio_register_get(ar->arWmi, gpioreg_id); } static A_STATUS ar6000_gpio_intr_ack(struct net_device *dev, A_UINT32 ack_mask) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); gpio_intr_available = FALSE; return wmi_gpio_intr_ack(ar->arWmi, ack_mask); } #endif /* CONFIG_HOST_GPIO_SUPPORT */ #if defined(CONFIG_TARGET_PROFILE_SUPPORT) static struct prof_count_s prof_count_results; static A_BOOL prof_count_available; /* Requested GPIO data available */ static A_STATUS prof_count_get(struct net_device *dev) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); *((volatile A_BOOL *)&prof_count_available) = FALSE; return wmi_prof_count_get_cmd(ar->arWmi); } /* * This is called when a response is received from the Target * for a previous prof_count_get call. */ void prof_count_rx(A_UINT32 addr, A_UINT32 count) { prof_count_results.addr = addr; prof_count_results.count = count; *((volatile A_BOOL *)&prof_count_available) = TRUE; wake_up(&arEvent); } #endif /* CONFIG_TARGET_PROFILE_SUPPORT */ static A_STATUS ar6000_create_acl_data_osbuf(struct net_device *dev, A_UINT8 *userdata, void **p_osbuf) { void *osbuf = NULL; A_UINT8 tmp_space[8]; HCI_ACL_DATA_PKT *acl; A_UINT8 hdr_size, *datap=NULL; A_STATUS ret = A_OK; /* ACL is in data path. There is a need to create pool * mechanism for allocating and freeing NETBUFs - ToDo later. */ *p_osbuf = NULL; acl = (HCI_ACL_DATA_PKT *)tmp_space; hdr_size = sizeof(acl->hdl_and_flags) + sizeof(acl->data_len); do { if (a_copy_from_user(acl, userdata, hdr_size)) { ret = A_EFAULT; break; } osbuf = A_NETBUF_ALLOC(hdr_size + acl->data_len); if (osbuf == NULL) { ret = A_NO_MEMORY; break; } A_NETBUF_PUT(osbuf, hdr_size + acl->data_len); datap = (A_UINT8 *)A_NETBUF_DATA(osbuf); /* Real copy to osbuf */ acl = (HCI_ACL_DATA_PKT *)(datap); A_MEMCPY(acl, tmp_space, hdr_size); if (a_copy_from_user(acl->data, userdata + hdr_size, acl->data_len)) { ret = A_EFAULT; break; } } while(FALSE); if (ret == A_OK) { *p_osbuf = osbuf; } else { A_NETBUF_FREE(osbuf); } return ret; } int ar6000_ioctl_ap_setparam(AR_SOFTC_T *ar, int param, int value) { int ret=0; switch(param) { case IEEE80211_PARAM_WPA: switch (value) { case WPA_MODE_WPA1: ar->arAuthMode = WPA_AUTH; break; case WPA_MODE_WPA2: ar->arAuthMode = WPA2_AUTH; break; case WPA_MODE_AUTO: ar->arAuthMode = WPA_AUTH | WPA2_AUTH; break; case WPA_MODE_NONE: ar->arAuthMode = NONE_AUTH; break; } break; case IEEE80211_PARAM_AUTHMODE: if(value == IEEE80211_AUTH_WPA_PSK) { if (WPA_AUTH == ar->arAuthMode) { ar->arAuthMode = WPA_PSK_AUTH; } else if (WPA2_AUTH == ar->arAuthMode) { ar->arAuthMode = WPA2_PSK_AUTH; } else if ((WPA_AUTH | WPA2_AUTH) == ar->arAuthMode) { ar->arAuthMode = WPA_PSK_AUTH | WPA2_PSK_AUTH; } else { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Error - Setting PSK "\ "mode when WPA param was set to %d\n", ar->arAuthMode)); ret = -EIO; } } break; case IEEE80211_PARAM_UCASTCIPHER: ar->arPairwiseCrypto = 0; if(value & (1<arPairwiseCrypto |= AES_CRYPT; } if(value & (1<arPairwiseCrypto |= TKIP_CRYPT; } if(!ar->arPairwiseCrypto) { AR_DEBUG_PRINTF(ATH_DEBUG_ERR, ("Error - Invalid cipher in WPA \n")); ret = -EIO; } break; case IEEE80211_PARAM_PRIVACY: if(value == 0) { ar->arDot11AuthMode = OPEN_AUTH; ar->arAuthMode = NONE_AUTH; ar->arPairwiseCrypto = NONE_CRYPT; ar->arPairwiseCryptoLen = 0; ar->arGroupCrypto = NONE_CRYPT; ar->arGroupCryptoLen = 0; } break; #ifdef WAPI_ENABLE case IEEE80211_PARAM_WAPI: A_PRINTF("WAPI Policy: %d\n", value); ar->arDot11AuthMode = OPEN_AUTH; ar->arAuthMode = NONE_AUTH; if(value & 0x1) { ar->arPairwiseCrypto = WAPI_CRYPT; ar->arGroupCrypto = WAPI_CRYPT; } else { ar->arPairwiseCrypto = NONE_CRYPT; ar->arGroupCrypto = NONE_CRYPT; } break; #endif } return ret; } int ar6000_ioctl_setparam(AR_SOFTC_T *ar, int param, int value) { A_BOOL profChanged = FALSE; int ret=0; if(ar->arNextMode == AP_NETWORK) { ar->ap_profile_flag = 1; /* There is a change in profile */ switch (param) { case IEEE80211_PARAM_WPA: case IEEE80211_PARAM_AUTHMODE: case IEEE80211_PARAM_UCASTCIPHER: case IEEE80211_PARAM_PRIVACY: case IEEE80211_PARAM_WAPI: ret = ar6000_ioctl_ap_setparam(ar, param, value); return ret; } } switch (param) { case IEEE80211_PARAM_WPA: switch (value) { case WPA_MODE_WPA1: ar->arAuthMode = WPA_AUTH; profChanged = TRUE; break; case WPA_MODE_WPA2: ar->arAuthMode = WPA2_AUTH; profChanged = TRUE; break; case WPA_MODE_NONE: ar->arAuthMode = NONE_AUTH; profChanged = TRUE; break; } break; case IEEE80211_PARAM_AUTHMODE: switch(value) { case IEEE80211_AUTH_WPA_PSK: if (WPA_AUTH == ar->arAuthMode) { ar->arAuthMode = WPA_PSK_AUTH; profChanged = TRUE; } else if (WPA2_AUTH == ar->arAuthMode) { ar->arAuthMode = WPA2_PSK_AUTH; profChanged = TRUE; } else { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("Error - Setting PSK "\ "mode when WPA param was set to %d\n", ar->arAuthMode)); ret = -EIO; } break; case IEEE80211_AUTH_WPA_CCKM: if (WPA2_AUTH == ar->arAuthMode) { ar->arAuthMode = WPA2_AUTH_CCKM; } else { ar->arAuthMode = WPA_AUTH_CCKM; } break; default: break; } break; case IEEE80211_PARAM_UCASTCIPHER: switch (value) { case IEEE80211_CIPHER_AES_CCM: ar->arPairwiseCrypto = AES_CRYPT; profChanged = TRUE; break; case IEEE80211_CIPHER_TKIP: ar->arPairwiseCrypto = TKIP_CRYPT; profChanged = TRUE; break; case IEEE80211_CIPHER_WEP: ar->arPairwiseCrypto = WEP_CRYPT; profChanged = TRUE; break; case IEEE80211_CIPHER_NONE: ar->arPairwiseCrypto = NONE_CRYPT; profChanged = TRUE; break; } break; case IEEE80211_PARAM_UCASTKEYLEN: if (!IEEE80211_IS_VALID_WEP_CIPHER_LEN(value)) { ret = -EIO; } else { ar->arPairwiseCryptoLen = value; } break; case IEEE80211_PARAM_MCASTCIPHER: switch (value) { case IEEE80211_CIPHER_AES_CCM: ar->arGroupCrypto = AES_CRYPT; profChanged = TRUE; break; case IEEE80211_CIPHER_TKIP: ar->arGroupCrypto = TKIP_CRYPT; profChanged = TRUE; break; case IEEE80211_CIPHER_WEP: ar->arGroupCrypto = WEP_CRYPT; profChanged = TRUE; break; case IEEE80211_CIPHER_NONE: ar->arGroupCrypto = NONE_CRYPT; profChanged = TRUE; break; } break; case IEEE80211_PARAM_MCASTKEYLEN: if (!IEEE80211_IS_VALID_WEP_CIPHER_LEN(value)) { ret = -EIO; } else { ar->arGroupCryptoLen = value; } break; case IEEE80211_PARAM_COUNTERMEASURES: if (ar->arWmiReady == FALSE) { return -EIO; } wmi_set_tkip_countermeasures_cmd(ar->arWmi, value); break; default: break; } if ((ar->arNextMode != AP_NETWORK) && (profChanged == TRUE)) { /* * profile has changed. Erase ssid to signal change */ A_MEMZERO(ar->arSsid, sizeof(ar->arSsid)); } return ret; } int ar6000_ioctl_setkey(AR_SOFTC_T *ar, struct ieee80211req_key *ik) { KEY_USAGE keyUsage; A_STATUS status; CRYPTO_TYPE keyType = NONE_CRYPT; #ifdef USER_KEYS ar->user_saved_keys.keyOk = FALSE; #endif if ( (0 == memcmp(ik->ik_macaddr, null_mac, IEEE80211_ADDR_LEN)) || (0 == memcmp(ik->ik_macaddr, bcast_mac, IEEE80211_ADDR_LEN)) ) { keyUsage = GROUP_USAGE; if(ar->arNextMode == AP_NETWORK) { A_MEMCPY(&ar->ap_mode_bkey, ik, sizeof(struct ieee80211req_key)); #ifdef WAPI_ENABLE if(ar->arPairwiseCrypto == WAPI_CRYPT) { return ap_set_wapi_key(ar, ik); } #endif } #ifdef USER_KEYS A_MEMCPY(&ar->user_saved_keys.bcast_ik, ik, sizeof(struct ieee80211req_key)); #endif } else { keyUsage = PAIRWISE_USAGE; #ifdef USER_KEYS A_MEMCPY(&ar->user_saved_keys.ucast_ik, ik, sizeof(struct ieee80211req_key)); #endif #ifdef WAPI_ENABLE if(ar->arNextMode == AP_NETWORK) { if(ar->arPairwiseCrypto == WAPI_CRYPT) { return ap_set_wapi_key(ar, ik); } } #endif } switch (ik->ik_type) { case IEEE80211_CIPHER_WEP: keyType = WEP_CRYPT; break; case IEEE80211_CIPHER_TKIP: keyType = TKIP_CRYPT; break; case IEEE80211_CIPHER_AES_CCM: keyType = AES_CRYPT; break; default: break; } #ifdef USER_KEYS ar->user_saved_keys.keyType = keyType; #endif if (IEEE80211_CIPHER_CCKM_KRK != ik->ik_type) { if (NONE_CRYPT == keyType) { return -EIO; } if (WEP_CRYPT == keyType) { int index = ik->ik_keyix; if (!IEEE80211_IS_VALID_WEP_CIPHER_LEN(ik->ik_keylen)) { return -EIO; } A_MEMZERO(ar->arWepKeyList[index].arKey, sizeof(ar->arWepKeyList[index].arKey)); A_MEMCPY(ar->arWepKeyList[index].arKey, ik->ik_keydata, ik->ik_keylen); ar->arWepKeyList[index].arKeyLen = ik->ik_keylen; if(ik->ik_flags & IEEE80211_KEY_DEFAULT){ ar->arDefTxKeyIndex = index; } return 0; } if (((WPA_PSK_AUTH == ar->arAuthMode) || (WPA2_PSK_AUTH == ar->arAuthMode)) && (GROUP_USAGE & keyUsage)) { A_UNTIMEOUT(&ar->disconnect_timer); } status = wmi_addKey_cmd(ar->arWmi, ik->ik_keyix, keyType, keyUsage, ik->ik_keylen, (A_UINT8 *)&ik->ik_keyrsc, ik->ik_keydata, KEY_OP_INIT_VAL, ik->ik_macaddr, SYNC_BOTH_WMIFLAG); if (status != A_OK) { return -EIO; } } else { status = wmi_add_krk_cmd(ar->arWmi, ik->ik_keydata); } #ifdef USER_KEYS ar->user_saved_keys.keyOk = TRUE; #endif return 0; } int ar6000_ioctl(struct net_device *dev, struct ifreq *rq, int cmd) { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); HIF_DEVICE *hifDevice = ar->arHifDevice; int ret = 0, param; unsigned int address = 0; unsigned int length = 0; unsigned char *buffer; char *userdata; A_UINT32 connectCtrlFlags; WMI_SET_AKMP_PARAMS_CMD akmpParams; WMI_SET_PMKID_LIST_CMD pmkidInfo; WMI_SET_HT_CAP_CMD htCap; WMI_SET_HT_OP_CMD htOp; /* * ioctl operations may have to wait for the Target, so we cannot hold rtnl. * Prevent the device from disappearing under us and release the lock during * the ioctl operation. */ dev_hold(dev); rtnl_unlock(); if (cmd == AR6000_IOCTL_EXTENDED) { /* * This allows for many more wireless ioctls than would otherwise * be available. Applications embed the actual ioctl command in * the first word of the parameter block, and use the command * AR6000_IOCTL_EXTENDED_CMD on the ioctl call. */ get_user(cmd, (int *)rq->ifr_data); userdata = (char *)(((unsigned int *)rq->ifr_data)+1); if(is_xioctl_allowed(ar->arNextMode, cmd) != A_OK) { A_PRINTF("xioctl: cmd=%d not allowed in this mode\n",cmd); ret = -EOPNOTSUPP; goto ioctl_done; } } else { A_STATUS ret = is_iwioctl_allowed(ar->arNextMode, cmd); if(ret == A_ENOTSUP) { A_PRINTF("iwioctl: cmd=0x%x not allowed in this mode\n", cmd); ret = -EOPNOTSUPP; goto ioctl_done; } else if (ret == A_ERROR) { /* It is not our ioctl (out of range ioctl) */ ret = -EOPNOTSUPP; goto ioctl_done; } userdata = (char *)rq->ifr_data; } if ((ar->arWlanState == WLAN_DISABLED) && ((cmd != AR6000_XIOCTRL_WMI_SET_WLAN_STATE) && (cmd != AR6000_XIOCTL_DIAG_READ) && (cmd != AR6000_XIOCTL_DIAG_WRITE))) { ret = -EIO; goto ioctl_done; } ret = 0; switch(cmd) { case IEEE80211_IOCTL_SETPARAM: { int param, value; int *ptr = (int *)rq->ifr_ifru.ifru_newname; if (ar->arWmiReady == FALSE) { ret = -EIO; } else { param = *ptr++; value = *ptr; ret = ar6000_ioctl_setparam(ar,param,value); } break; } case IEEE80211_IOCTL_SETKEY: { struct ieee80211req_key keydata; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&keydata, userdata, sizeof(struct ieee80211req_key))) { ret = -EFAULT; } else { ar6000_ioctl_setkey(ar, &keydata); } break; } case IEEE80211_IOCTL_DELKEY: case IEEE80211_IOCTL_SETOPTIE: { //ret = -EIO; break; } case IEEE80211_IOCTL_SETMLME: { struct ieee80211req_mlme mlme; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&mlme, userdata, sizeof(struct ieee80211req_mlme))) { ret = -EFAULT; } else { switch (mlme.im_op) { case IEEE80211_MLME_AUTHORIZE: A_PRINTF("setmlme AUTHORIZE %02X:%02X\n", mlme.im_macaddr[4], mlme.im_macaddr[5]); break; case IEEE80211_MLME_UNAUTHORIZE: A_PRINTF("setmlme UNAUTHORIZE %02X:%02X\n", mlme.im_macaddr[4], mlme.im_macaddr[5]); break; case IEEE80211_MLME_DEAUTH: A_PRINTF("setmlme DEAUTH %02X:%02X\n", mlme.im_macaddr[4], mlme.im_macaddr[5]); //remove_sta(ar, mlme.im_macaddr); break; case IEEE80211_MLME_DISASSOC: A_PRINTF("setmlme DISASSOC %02X:%02X\n", mlme.im_macaddr[4], mlme.im_macaddr[5]); //remove_sta(ar, mlme.im_macaddr); break; default: ret = 0; goto ioctl_done; } wmi_ap_set_mlme(ar->arWmi, mlme.im_op, mlme.im_macaddr, mlme.im_reason); } break; } case IEEE80211_IOCTL_ADDPMKID: { struct ieee80211req_addpmkid req; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&req, userdata, sizeof(struct ieee80211req_addpmkid))) { ret = -EFAULT; } else { A_STATUS status; AR_DEBUG_PRINTF(ATH_DEBUG_WLAN_CONNECT,("Add pmkid for %2.2x:%2.2x:%2.2x:%2.2x:%2.2x:%2.2x en=%d\n", req.pi_bssid[0], req.pi_bssid[1], req.pi_bssid[2], req.pi_bssid[3], req.pi_bssid[4], req.pi_bssid[5], req.pi_enable)); status = wmi_setPmkid_cmd(ar->arWmi, req.pi_bssid, req.pi_pmkid, req.pi_enable); if (status != A_OK) { ret = -EIO; goto ioctl_done; } } break; } #ifdef CONFIG_HOST_TCMD_SUPPORT case AR6000_XIOCTL_TCMD_CONT_TX: { TCMD_CONT_TX txCmd; if (ar->tcmdPm == TCMD_PM_SLEEP) { A_PRINTF("Can NOT send tx tcmd when target is asleep! \n"); ret = -EFAULT; goto ioctl_done; } if(copy_from_user(&txCmd, userdata, sizeof(TCMD_CONT_TX))) { ret = -EFAULT; goto ioctl_done; } else { wmi_test_cmd(ar->arWmi,(A_UINT8 *)&txCmd, sizeof(TCMD_CONT_TX)); } } break; case AR6000_XIOCTL_TCMD_CONT_RX: { TCMD_CONT_RX rxCmd; if (ar->tcmdPm == TCMD_PM_SLEEP) { A_PRINTF("Can NOT send rx tcmd when target is asleep! \n"); ret = -EFAULT; goto ioctl_done; } if(copy_from_user(&rxCmd, userdata, sizeof(TCMD_CONT_RX))) { ret = -EFAULT; goto ioctl_done; } switch(rxCmd.act) { case TCMD_CONT_RX_PROMIS: case TCMD_CONT_RX_FILTER: case TCMD_CONT_RX_SETMAC: case TCMD_CONT_RX_SET_ANT_SWITCH_TABLE: wmi_test_cmd(ar->arWmi,(A_UINT8 *)&rxCmd, sizeof(TCMD_CONT_RX)); tcmdRxFreq = rxCmd.u.para.freq; break; case TCMD_CONT_RX_REPORT: ar6000_ioctl_tcmd_get_rx_report(dev, rq, (A_UINT8 *)&rxCmd, sizeof(TCMD_CONT_RX)); break; default: A_PRINTF("Unknown Cont Rx mode: %d\n",rxCmd.act); ret = -EINVAL; goto ioctl_done; } } break; case AR6000_XIOCTL_TCMD_PM: { TCMD_PM pmCmd; if(copy_from_user(&pmCmd, userdata, sizeof(TCMD_PM))) { ret = -EFAULT; goto ioctl_done; } ar->tcmdPm = pmCmd.mode; wmi_test_cmd(ar->arWmi, (A_UINT8*)&pmCmd, sizeof(TCMD_PM)); } break; #endif /* CONFIG_HOST_TCMD_SUPPORT */ case AR6000_XIOCTL_BMI_DONE: if(bmienable) { rtnl_lock(); /* ar6000_init expects to be called holding rtnl lock */ ret = ar6000_init(dev); rtnl_unlock(); } else { ret = BMIDone(hifDevice); } break; case AR6000_XIOCTL_BMI_READ_MEMORY: get_user(address, (unsigned int *)userdata); get_user(length, (unsigned int *)userdata + 1); AR_DEBUG_PRINTF(ATH_DEBUG_INFO,("Read Memory (address: 0x%x, length: %d)\n", address, length)); if ((buffer = (unsigned char *)A_MALLOC(length)) != NULL) { A_MEMZERO(buffer, length); ret = BMIReadMemory(hifDevice, address, buffer, length); if (copy_to_user(rq->ifr_data, buffer, length)) { ret = -EFAULT; } A_FREE(buffer); } else { ret = -ENOMEM; } break; case AR6000_XIOCTL_BMI_WRITE_MEMORY: get_user(address, (unsigned int *)userdata); get_user(length, (unsigned int *)userdata + 1); AR_DEBUG_PRINTF(ATH_DEBUG_INFO,("Write Memory (address: 0x%x, length: %d)\n", address, length)); if ((buffer = (unsigned char *)A_MALLOC(length)) != NULL) { A_MEMZERO(buffer, length); if (copy_from_user(buffer, &userdata[sizeof(address) + sizeof(length)], length)) { ret = -EFAULT; } else { ret = BMIWriteMemory(hifDevice, address, buffer, length); } A_FREE(buffer); } else { ret = -ENOMEM; } break; case AR6000_XIOCTL_BMI_TEST: AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("No longer supported\n")); ret = -EOPNOTSUPP; break; case AR6000_XIOCTL_BMI_EXECUTE: get_user(address, (unsigned int *)userdata); get_user(param, (unsigned int *)userdata + 1); AR_DEBUG_PRINTF(ATH_DEBUG_INFO,("Execute (address: 0x%x, param: %d)\n", address, param)); ret = BMIExecute(hifDevice, address, (A_UINT32*)¶m); put_user(param, (unsigned int *)rq->ifr_data); /* return value */ break; case AR6000_XIOCTL_BMI_SET_APP_START: get_user(address, (unsigned int *)userdata); AR_DEBUG_PRINTF(ATH_DEBUG_INFO,("Set App Start (address: 0x%x)\n", address)); ret = BMISetAppStart(hifDevice, address); break; case AR6000_XIOCTL_BMI_READ_SOC_REGISTER: get_user(address, (unsigned int *)userdata); ret = BMIReadSOCRegister(hifDevice, address, (A_UINT32*)¶m); put_user(param, (unsigned int *)rq->ifr_data); /* return value */ break; case AR6000_XIOCTL_BMI_WRITE_SOC_REGISTER: get_user(address, (unsigned int *)userdata); get_user(param, (unsigned int *)userdata + 1); ret = BMIWriteSOCRegister(hifDevice, address, param); break; #ifdef HTC_RAW_INTERFACE case AR6000_XIOCTL_HTC_RAW_OPEN: ret = A_OK; if (!arRawIfEnabled(ar)) { /* make sure block size is set in case the target was reset since last * BMI phase (i.e. flashup downloads) */ ret = ar6000_set_htc_params(ar->arHifDevice, ar->arTargetType, 0, /* use default yield */ 0 /* use default number of HTC ctrl buffers */ ); if (A_FAILED(ret)) { break; } /* Terminate the BMI phase */ ret = BMIDone(hifDevice); if (ret == A_OK) { ret = ar6000_htc_raw_open(ar); } } break; case AR6000_XIOCTL_HTC_RAW_CLOSE: if (arRawIfEnabled(ar)) { ret = ar6000_htc_raw_close(ar); arRawIfEnabled(ar) = FALSE; } else { ret = A_ERROR; } break; case AR6000_XIOCTL_HTC_RAW_READ: if (arRawIfEnabled(ar)) { unsigned int streamID; get_user(streamID, (unsigned int *)userdata); get_user(length, (unsigned int *)userdata + 1); buffer = rq->ifr_data + sizeof(length); ret = ar6000_htc_raw_read(ar, (HTC_RAW_STREAM_ID)streamID, buffer, length); put_user(ret, (unsigned int *)rq->ifr_data); } else { ret = A_ERROR; } break; case AR6000_XIOCTL_HTC_RAW_WRITE: if (arRawIfEnabled(ar)) { unsigned int streamID; get_user(streamID, (unsigned int *)userdata); get_user(length, (unsigned int *)userdata + 1); buffer = userdata + sizeof(streamID) + sizeof(length); ret = ar6000_htc_raw_write(ar, (HTC_RAW_STREAM_ID)streamID, buffer, length); put_user(ret, (unsigned int *)rq->ifr_data); } else { ret = A_ERROR; } break; #endif /* HTC_RAW_INTERFACE */ case AR6000_XIOCTL_BMI_LZ_STREAM_START: get_user(address, (unsigned int *)userdata); AR_DEBUG_PRINTF(ATH_DEBUG_INFO,("Start Compressed Stream (address: 0x%x)\n", address)); ret = BMILZStreamStart(hifDevice, address); break; case AR6000_XIOCTL_BMI_LZ_DATA: get_user(length, (unsigned int *)userdata); AR_DEBUG_PRINTF(ATH_DEBUG_INFO,("Send Compressed Data (length: %d)\n", length)); if ((buffer = (unsigned char *)A_MALLOC(length)) != NULL) { A_MEMZERO(buffer, length); if (copy_from_user(buffer, &userdata[sizeof(length)], length)) { ret = -EFAULT; } else { ret = BMILZData(hifDevice, buffer, length); } A_FREE(buffer); } else { ret = -ENOMEM; } break; #if defined(CONFIG_TARGET_PROFILE_SUPPORT) /* * Optional support for Target-side profiling. * Not needed in production. */ /* Configure Target-side profiling */ case AR6000_XIOCTL_PROF_CFG: { A_UINT32 period; A_UINT32 nbins; get_user(period, (unsigned int *)userdata); get_user(nbins, (unsigned int *)userdata + 1); if (wmi_prof_cfg_cmd(ar->arWmi, period, nbins) != A_OK) { ret = -EIO; } break; } /* Start a profiling bucket/bin at the specified address */ case AR6000_XIOCTL_PROF_ADDR_SET: { A_UINT32 addr; get_user(addr, (unsigned int *)userdata); if (wmi_prof_addr_set_cmd(ar->arWmi, addr) != A_OK) { ret = -EIO; } break; } /* START Target-side profiling */ case AR6000_XIOCTL_PROF_START: wmi_prof_start_cmd(ar->arWmi); break; /* STOP Target-side profiling */ case AR6000_XIOCTL_PROF_STOP: wmi_prof_stop_cmd(ar->arWmi); break; case AR6000_XIOCTL_PROF_COUNT_GET: { if (ar->bIsDestroyProgress) { ret = -EBUSY; goto ioctl_done; } if (ar->arWmiReady == FALSE) { ret = -EIO; goto ioctl_done; } if (down_interruptible(&ar->arSem)) { ret = -ERESTARTSYS; goto ioctl_done; } if (ar->bIsDestroyProgress) { up(&ar->arSem); ret = -EBUSY; goto ioctl_done; } prof_count_available = FALSE; ret = prof_count_get(dev); if (ret != A_OK) { up(&ar->arSem); ret = -EIO; goto ioctl_done; } /* Wait for Target to respond. */ wait_event_interruptible(arEvent, prof_count_available); if (signal_pending(current)) { ret = -EINTR; } else { if (copy_to_user(userdata, &prof_count_results, sizeof(prof_count_results))) { ret = -EFAULT; } } up(&ar->arSem); break; } #endif /* CONFIG_TARGET_PROFILE_SUPPORT */ case AR6000_IOCTL_WMI_GETREV: { if (copy_to_user(rq->ifr_data, &ar->arVersion, sizeof(ar->arVersion))) { ret = -EFAULT; } break; } case AR6000_IOCTL_WMI_SETPWR: { WMI_POWER_MODE_CMD pwrModeCmd; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&pwrModeCmd, userdata, sizeof(pwrModeCmd))) { ret = -EFAULT; } else { if (wmi_powermode_cmd(ar->arWmi, pwrModeCmd.powerMode) != A_OK) { ret = -EIO; } } break; } case AR6000_IOCTL_WMI_SET_IBSS_PM_CAPS: { WMI_IBSS_PM_CAPS_CMD ibssPmCaps; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&ibssPmCaps, userdata, sizeof(ibssPmCaps))) { ret = -EFAULT; } else { if (wmi_ibsspmcaps_cmd(ar->arWmi, ibssPmCaps.power_saving, ibssPmCaps.ttl, ibssPmCaps.atim_windows, ibssPmCaps.timeout_value) != A_OK) { ret = -EIO; } AR6000_SPIN_LOCK(&ar->arLock, 0); ar->arIbssPsEnable = ibssPmCaps.power_saving; AR6000_SPIN_UNLOCK(&ar->arLock, 0); } break; } case AR6000_XIOCTL_WMI_SET_AP_PS: { WMI_AP_PS_CMD apPsCmd; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&apPsCmd, userdata, sizeof(apPsCmd))) { ret = -EFAULT; } else { if (wmi_apps_cmd(ar->arWmi, apPsCmd.psType, apPsCmd.idle_time, apPsCmd.ps_period, apPsCmd.sleep_period) != A_OK) { ret = -EIO; } } break; } case AR6000_IOCTL_WMI_SET_PMPARAMS: { WMI_POWER_PARAMS_CMD pmParams; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&pmParams, userdata, sizeof(pmParams))) { ret = -EFAULT; } else { if (wmi_pmparams_cmd(ar->arWmi, pmParams.idle_period, pmParams.pspoll_number, pmParams.dtim_policy, pmParams.tx_wakeup_policy, pmParams.num_tx_to_wakeup, #if WLAN_CONFIG_IGNORE_POWER_SAVE_FAIL_EVENT_DURING_SCAN IGNORE_POWER_SAVE_FAIL_EVENT_DURING_SCAN #else SEND_POWER_SAVE_FAIL_EVENT_ALWAYS #endif ) != A_OK) { ret = -EIO; } } break; } case AR6000_IOCTL_WMI_SETSCAN: { if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&ar->scParams, userdata, sizeof(ar->scParams))) { ret = -EFAULT; } else { if (CAN_SCAN_IN_CONNECT(ar->scParams.scanCtrlFlags)) { ar->arSkipScan = FALSE; } else { ar->arSkipScan = TRUE; } if (wmi_scanparams_cmd(ar->arWmi, ar->scParams.fg_start_period, ar->scParams.fg_end_period, ar->scParams.bg_period, ar->scParams.minact_chdwell_time, ar->scParams.maxact_chdwell_time, ar->scParams.pas_chdwell_time, ar->scParams.shortScanRatio, ar->scParams.scanCtrlFlags, ar->scParams.max_dfsch_act_time, ar->scParams.maxact_scan_per_ssid) != A_OK) { ret = -EIO; } } break; } case AR6000_IOCTL_WMI_SETLISTENINT: { WMI_LISTEN_INT_CMD listenCmd; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&listenCmd, userdata, sizeof(listenCmd))) { ret = -EFAULT; } else { if (wmi_listeninterval_cmd(ar->arWmi, listenCmd.listenInterval, listenCmd.numBeacons) != A_OK) { ret = -EIO; } else { AR6000_SPIN_LOCK(&ar->arLock, 0); ar->arListenInterval = param; AR6000_SPIN_UNLOCK(&ar->arLock, 0); } } break; } case AR6000_IOCTL_WMI_SET_BMISS_TIME: { WMI_BMISS_TIME_CMD bmissCmd; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&bmissCmd, userdata, sizeof(bmissCmd))) { ret = -EFAULT; } else { if (wmi_bmisstime_cmd(ar->arWmi, bmissCmd.bmissTime, bmissCmd.numBeacons) != A_OK) { ret = -EIO; } } break; } case AR6000_IOCTL_WMI_SETBSSFILTER: { WMI_BSS_FILTER_CMD filt; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&filt, userdata, sizeof(filt))) { ret = -EFAULT; } else { if (wmi_bssfilter_cmd(ar->arWmi, filt.bssFilter, filt.ieMask) != A_OK) { ret = -EIO; } else { ar->arUserBssFilter = param; } } break; } case AR6000_IOCTL_WMI_SET_SNRTHRESHOLD: { ret = ar6000_ioctl_set_snr_threshold(dev, rq); break; } case AR6000_XIOCTL_WMI_SET_RSSITHRESHOLD: { ret = ar6000_ioctl_set_rssi_threshold(dev, rq); break; } case AR6000_XIOCTL_WMI_CLR_RSSISNR: { if (ar->arWmiReady == FALSE) { ret = -EIO; } ret = wmi_clr_rssi_snr(ar->arWmi); break; } case AR6000_XIOCTL_WMI_SET_LQTHRESHOLD: { ret = ar6000_ioctl_set_lq_threshold(dev, rq); break; } case AR6000_XIOCTL_WMI_SET_LPREAMBLE: { WMI_SET_LPREAMBLE_CMD setLpreambleCmd; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&setLpreambleCmd, userdata, sizeof(setLpreambleCmd))) { ret = -EFAULT; } else { if (wmi_set_lpreamble_cmd(ar->arWmi, setLpreambleCmd.status, #if WLAN_CONFIG_DONOT_IGNORE_BARKER_IN_ERP WMI_DONOT_IGNORE_BARKER_IN_ERP #else WMI_IGNORE_BARKER_IN_ERP #endif ) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_WMI_SET_RTS: { WMI_SET_RTS_CMD rtsCmd; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&rtsCmd, userdata, sizeof(rtsCmd))) { ret = -EFAULT; } else { ar->arRTS = rtsCmd.threshold; if (wmi_set_rts_cmd(ar->arWmi, rtsCmd.threshold) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_WMI_SET_WMM: { ret = ar6000_ioctl_set_wmm(dev, rq); break; } case AR6000_XIOCTL_WMI_SET_QOS_SUPP: { ret = ar6000_ioctl_set_qos_supp(dev, rq); break; } case AR6000_XIOCTL_WMI_SET_TXOP: { ret = ar6000_ioctl_set_txop(dev, rq); break; } case AR6000_XIOCTL_WMI_GET_RD: { ret = ar6000_ioctl_get_rd(dev, rq); break; } case AR6000_IOCTL_WMI_SET_CHANNELPARAMS: { ret = ar6000_ioctl_set_channelParams(dev, rq); break; } case AR6000_IOCTL_WMI_SET_PROBEDSSID: { ret = ar6000_ioctl_set_probedSsid(dev, rq); break; } case AR6000_IOCTL_WMI_SET_BADAP: { ret = ar6000_ioctl_set_badAp(dev, rq); break; } case AR6000_IOCTL_WMI_CREATE_QOS: { ret = ar6000_ioctl_create_qos(dev, rq); break; } case AR6000_IOCTL_WMI_DELETE_QOS: { ret = ar6000_ioctl_delete_qos(dev, rq); break; } case AR6000_IOCTL_WMI_GET_QOS_QUEUE: { ret = ar6000_ioctl_get_qos_queue(dev, rq); break; } case AR6000_IOCTL_WMI_GET_TARGET_STATS: { ret = ar6000_ioctl_get_target_stats(dev, rq); break; } case AR6000_IOCTL_WMI_SET_ERROR_REPORT_BITMASK: { ret = ar6000_ioctl_set_error_report_bitmask(dev, rq); break; } case AR6000_IOCTL_WMI_SET_ASSOC_INFO: { WMI_SET_ASSOC_INFO_CMD cmd; A_UINT8 assocInfo[WMI_MAX_ASSOC_INFO_LEN]; if (ar->arWmiReady == FALSE) { ret = -EIO; } else { get_user(cmd.ieType, userdata); if (cmd.ieType >= WMI_MAX_ASSOC_INFO_TYPE) { ret = -EIO; } else { get_user(cmd.bufferSize, userdata + 1); if (cmd.bufferSize > WMI_MAX_ASSOC_INFO_LEN) { ret = -EFAULT; break; } if (copy_from_user(assocInfo, userdata + 2, cmd.bufferSize)) { ret = -EFAULT; } else { if (wmi_associnfo_cmd(ar->arWmi, cmd.ieType, cmd.bufferSize, assocInfo) != A_OK) { ret = -EIO; } } } } break; } case AR6000_IOCTL_WMI_SET_ACCESS_PARAMS: { ret = ar6000_ioctl_set_access_params(dev, rq); break; } case AR6000_IOCTL_WMI_SET_DISC_TIMEOUT: { ret = ar6000_ioctl_set_disconnect_timeout(dev, rq); break; } case AR6000_XIOCTL_FORCE_TARGET_RESET: { if (ar->arHtcTarget) { // HTCForceReset(htcTarget); } else { AR_DEBUG_PRINTF(ATH_DEBUG_WARN,("ar6000_ioctl cannot attempt reset.\n")); } break; } case AR6000_XIOCTL_TARGET_INFO: case AR6000_XIOCTL_CHECK_TARGET_READY: /* backwards compatibility */ { /* If we made it to here, then the Target exists and is ready. */ if (cmd == AR6000_XIOCTL_TARGET_INFO) { if (copy_to_user((A_UINT32 *)rq->ifr_data, &ar->arVersion.target_ver, sizeof(ar->arVersion.target_ver))) { ret = -EFAULT; } if (copy_to_user(((A_UINT32 *)rq->ifr_data)+1, &ar->arTargetType, sizeof(ar->arTargetType))) { ret = -EFAULT; } } break; } case AR6000_XIOCTL_WMI_SET_HB_CHALLENGE_RESP_PARAMS: { WMI_SET_HB_CHALLENGE_RESP_PARAMS_CMD hbparam; if (copy_from_user(&hbparam, userdata, sizeof(hbparam))) { ret = -EFAULT; } else { AR6000_SPIN_LOCK(&ar->arLock, 0); /* Start a cyclic timer with the parameters provided. */ if (hbparam.frequency) { ar->arHBChallengeResp.frequency = hbparam.frequency; } if (hbparam.threshold) { ar->arHBChallengeResp.missThres = hbparam.threshold; } /* Delete the pending timer and start a new one */ if (timer_pending(&ar->arHBChallengeResp.timer)) { A_UNTIMEOUT(&ar->arHBChallengeResp.timer); } A_TIMEOUT_MS(&ar->arHBChallengeResp.timer, ar->arHBChallengeResp.frequency * 1000, 0); AR6000_SPIN_UNLOCK(&ar->arLock, 0); } break; } case AR6000_XIOCTL_WMI_GET_HB_CHALLENGE_RESP: { A_UINT32 cookie; if (copy_from_user(&cookie, userdata, sizeof(cookie))) { ret = -EFAULT; goto ioctl_done; } /* Send the challenge on the control channel */ if (wmi_get_challenge_resp_cmd(ar->arWmi, cookie, APP_HB_CHALLENGE) != A_OK) { ret = -EIO; goto ioctl_done; } break; } #ifdef USER_KEYS case AR6000_XIOCTL_USER_SETKEYS: { ar->user_savedkeys_stat = USER_SAVEDKEYS_STAT_RUN; if (copy_from_user(&ar->user_key_ctrl, userdata, sizeof(ar->user_key_ctrl))) { ret = -EFAULT; goto ioctl_done; } A_PRINTF("ar6000 USER set key %x\n", ar->user_key_ctrl); break; } #endif /* USER_KEYS */ #ifdef CONFIG_HOST_GPIO_SUPPORT case AR6000_XIOCTL_GPIO_OUTPUT_SET: { struct ar6000_gpio_output_set_cmd_s gpio_output_set_cmd; if (ar->bIsDestroyProgress) { ret = -EBUSY; goto ioctl_done; } if (ar->arWmiReady == FALSE) { ret = -EIO; goto ioctl_done; } if (down_interruptible(&ar->arSem)) { ret = -ERESTARTSYS; goto ioctl_done; } if (ar->bIsDestroyProgress) { up(&ar->arSem); ret = -EBUSY; goto ioctl_done; } if (copy_from_user(&gpio_output_set_cmd, userdata, sizeof(gpio_output_set_cmd))) { ret = -EFAULT; } else { ret = ar6000_gpio_output_set(dev, gpio_output_set_cmd.set_mask, gpio_output_set_cmd.clear_mask, gpio_output_set_cmd.enable_mask, gpio_output_set_cmd.disable_mask); if (ret != A_OK) { ret = EIO; } } up(&ar->arSem); break; } case AR6000_XIOCTL_GPIO_INPUT_GET: { if (ar->bIsDestroyProgress) { ret = -EBUSY; goto ioctl_done; } if (ar->arWmiReady == FALSE) { ret = -EIO; goto ioctl_done; } if (down_interruptible(&ar->arSem)) { ret = -ERESTARTSYS; goto ioctl_done; } if (ar->bIsDestroyProgress) { up(&ar->arSem); ret = -EBUSY; goto ioctl_done; } ret = ar6000_gpio_input_get(dev); if (ret != A_OK) { up(&ar->arSem); ret = -EIO; goto ioctl_done; } /* Wait for Target to respond. */ wait_event_interruptible(arEvent, gpio_data_available); if (signal_pending(current)) { ret = -EINTR; } else { A_ASSERT(gpio_reg_results.gpioreg_id == GPIO_ID_NONE); if (copy_to_user(userdata, &gpio_reg_results.value, sizeof(gpio_reg_results.value))) { ret = -EFAULT; } } up(&ar->arSem); break; } case AR6000_XIOCTL_GPIO_REGISTER_SET: { struct ar6000_gpio_register_cmd_s gpio_register_cmd; if (ar->bIsDestroyProgress) { ret = -EBUSY; goto ioctl_done; } if (ar->arWmiReady == FALSE) { ret = -EIO; goto ioctl_done; } if (down_interruptible(&ar->arSem)) { ret = -ERESTARTSYS; goto ioctl_done; } if (ar->bIsDestroyProgress) { up(&ar->arSem); ret = -EBUSY; goto ioctl_done; } if (copy_from_user(&gpio_register_cmd, userdata, sizeof(gpio_register_cmd))) { ret = -EFAULT; } else { ret = ar6000_gpio_register_set(dev, gpio_register_cmd.gpioreg_id, gpio_register_cmd.value); if (ret != A_OK) { ret = EIO; } /* Wait for acknowledgement from Target */ wait_event_interruptible(arEvent, gpio_ack_received); if (signal_pending(current)) { ret = -EINTR; } } up(&ar->arSem); break; } case AR6000_XIOCTL_GPIO_REGISTER_GET: { struct ar6000_gpio_register_cmd_s gpio_register_cmd; if (ar->bIsDestroyProgress) { ret = -EBUSY; goto ioctl_done; } if (ar->arWmiReady == FALSE) { ret = -EIO; goto ioctl_done; } if (down_interruptible(&ar->arSem)) { ret = -ERESTARTSYS; goto ioctl_done; } if (ar->bIsDestroyProgress) { up(&ar->arSem); ret = -EBUSY; goto ioctl_done; } if (copy_from_user(&gpio_register_cmd, userdata, sizeof(gpio_register_cmd))) { ret = -EFAULT; } else { ret = ar6000_gpio_register_get(dev, gpio_register_cmd.gpioreg_id); if (ret != A_OK) { up(&ar->arSem); ret = -EIO; goto ioctl_done; } /* Wait for Target to respond. */ wait_event_interruptible(arEvent, gpio_data_available); if (signal_pending(current)) { ret = -EINTR; } else { A_ASSERT(gpio_register_cmd.gpioreg_id == gpio_reg_results.gpioreg_id); if (copy_to_user(userdata, &gpio_reg_results, sizeof(gpio_reg_results))) { ret = -EFAULT; } } } up(&ar->arSem); break; } case AR6000_XIOCTL_GPIO_INTR_ACK: { struct ar6000_gpio_intr_ack_cmd_s gpio_intr_ack_cmd; if (ar->bIsDestroyProgress) { ret = -EBUSY; goto ioctl_done; } if (ar->arWmiReady == FALSE) { ret = -EIO; goto ioctl_done; } if (down_interruptible(&ar->arSem)) { ret = -ERESTARTSYS; goto ioctl_done; } if (ar->bIsDestroyProgress) { up(&ar->arSem); ret = -EBUSY; goto ioctl_done; } if (copy_from_user(&gpio_intr_ack_cmd, userdata, sizeof(gpio_intr_ack_cmd))) { ret = -EFAULT; } else { ret = ar6000_gpio_intr_ack(dev, gpio_intr_ack_cmd.ack_mask); if (ret != A_OK) { ret = EIO; } } up(&ar->arSem); break; } case AR6000_XIOCTL_GPIO_INTR_WAIT: { /* Wait for Target to report an interrupt. */ wait_event_interruptible(arEvent, gpio_intr_available); if (signal_pending(current)) { ret = -EINTR; } else { if (copy_to_user(userdata, &gpio_intr_results, sizeof(gpio_intr_results))) { ret = -EFAULT; } } break; } #endif /* CONFIG_HOST_GPIO_SUPPORT */ case AR6000_XIOCTL_DBGLOG_CFG_MODULE: { struct ar6000_dbglog_module_config_s config; if (copy_from_user(&config, userdata, sizeof(config))) { ret = -EFAULT; goto ioctl_done; } /* Send the challenge on the control channel */ if (wmi_config_debug_module_cmd(ar->arWmi, config.mmask, config.tsr, config.rep, config.size, config.valid) != A_OK) { ret = -EIO; goto ioctl_done; } break; } case AR6000_XIOCTL_DBGLOG_GET_DEBUG_LOGS: { /* Send the challenge on the control channel */ if (ar6000_dbglog_get_debug_logs(ar) != A_OK) { ret = -EIO; goto ioctl_done; } break; } case AR6000_XIOCTL_SET_ADHOC_BSSID: { WMI_SET_ADHOC_BSSID_CMD adhocBssid; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&adhocBssid, userdata, sizeof(adhocBssid))) { ret = -EFAULT; } else if (A_MEMCMP(adhocBssid.bssid, bcast_mac, AR6000_ETH_ADDR_LEN) == 0) { ret = -EFAULT; } else { A_MEMCPY(ar->arReqBssid, adhocBssid.bssid, sizeof(ar->arReqBssid)); } break; } case AR6000_XIOCTL_SET_OPT_MODE: { WMI_SET_OPT_MODE_CMD optModeCmd; AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&optModeCmd, userdata, sizeof(optModeCmd))) { ret = -EFAULT; } else if (ar->arConnected && optModeCmd.optMode == SPECIAL_ON) { ret = -EFAULT; } else if (wmi_set_opt_mode_cmd(ar->arWmi, optModeCmd.optMode) != A_OK) { ret = -EIO; } break; } case AR6000_XIOCTL_OPT_SEND_FRAME: { WMI_OPT_TX_FRAME_CMD optTxFrmCmd; A_UINT8 data[MAX_OPT_DATA_LEN]; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&optTxFrmCmd, userdata, sizeof(optTxFrmCmd))) { ret = -EFAULT; } else if (copy_from_user(data, userdata+sizeof(WMI_OPT_TX_FRAME_CMD)-1, optTxFrmCmd.optIEDataLen)) { ret = -EFAULT; } else { ret = wmi_opt_tx_frame_cmd(ar->arWmi, optTxFrmCmd.frmType, optTxFrmCmd.dstAddr, optTxFrmCmd.bssid, optTxFrmCmd.optIEDataLen, data); } break; } case AR6000_XIOCTL_WMI_SETRETRYLIMITS: { WMI_SET_RETRY_LIMITS_CMD setRetryParams; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&setRetryParams, userdata, sizeof(setRetryParams))) { ret = -EFAULT; } else { if (wmi_set_retry_limits_cmd(ar->arWmi, setRetryParams.frameType, setRetryParams.trafficClass, setRetryParams.maxRetries, setRetryParams.enableNotify) != A_OK) { ret = -EIO; } AR6000_SPIN_LOCK(&ar->arLock, 0); ar->arMaxRetries = setRetryParams.maxRetries; AR6000_SPIN_UNLOCK(&ar->arLock, 0); } break; } case AR6000_XIOCTL_SET_BEACON_INTVAL: { WMI_BEACON_INT_CMD bIntvlCmd; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&bIntvlCmd, userdata, sizeof(bIntvlCmd))) { ret = -EFAULT; } else if (wmi_set_adhoc_bconIntvl_cmd(ar->arWmi, bIntvlCmd.beaconInterval) != A_OK) { ret = -EIO; } if(ret == 0) { ar->ap_beacon_interval = bIntvlCmd.beaconInterval; ar->ap_profile_flag = 1; /* There is a change in profile */ } break; } case IEEE80211_IOCTL_SETAUTHALG: { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); struct ieee80211req_authalg req; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&req, userdata, sizeof(struct ieee80211req_authalg))) { ret = -EFAULT; } else { if (req.auth_alg & AUTH_ALG_OPEN_SYSTEM) { ar->arDot11AuthMode |= OPEN_AUTH; ar->arPairwiseCrypto = NONE_CRYPT; ar->arGroupCrypto = NONE_CRYPT; } if (req.auth_alg & AUTH_ALG_SHARED_KEY) { ar->arDot11AuthMode |= SHARED_AUTH; ar->arPairwiseCrypto = WEP_CRYPT; ar->arGroupCrypto = WEP_CRYPT; ar->arAuthMode = NONE_AUTH; } if (req.auth_alg == AUTH_ALG_LEAP) { ar->arDot11AuthMode = LEAP_AUTH; } } break; } case AR6000_XIOCTL_SET_VOICE_PKT_SIZE: ret = ar6000_xioctl_set_voice_pkt_size(dev, userdata); break; case AR6000_XIOCTL_SET_MAX_SP: ret = ar6000_xioctl_set_max_sp_len(dev, userdata); break; case AR6000_XIOCTL_WMI_GET_ROAM_TBL: ret = ar6000_ioctl_get_roam_tbl(dev, rq); break; case AR6000_XIOCTL_WMI_SET_ROAM_CTRL: ret = ar6000_ioctl_set_roam_ctrl(dev, userdata); break; case AR6000_XIOCTRL_WMI_SET_POWERSAVE_TIMERS: ret = ar6000_ioctl_set_powersave_timers(dev, userdata); break; case AR6000_XIOCTRL_WMI_GET_POWER_MODE: ret = ar6000_ioctl_get_power_mode(dev, rq); break; case AR6000_XIOCTRL_WMI_SET_WLAN_STATE: { AR6000_WLAN_STATE state; get_user(state, (unsigned int *)userdata); if (ar6000_set_wlan_state(ar, state)!=A_OK) { ret = -EIO; } break; } case AR6000_XIOCTL_WMI_GET_ROAM_DATA: ret = ar6000_ioctl_get_roam_data(dev, rq); break; case AR6000_XIOCTL_WMI_SET_BT_STATUS: ret = ar6000_xioctl_set_bt_status_cmd(dev, userdata); break; case AR6000_XIOCTL_WMI_SET_BT_PARAMS: ret = ar6000_xioctl_set_bt_params_cmd(dev, userdata); break; case AR6000_XIOCTL_WMI_SET_BTCOEX_FE_ANT: ret = ar6000_xioctl_set_btcoex_fe_ant_cmd(dev, userdata); break; case AR6000_XIOCTL_WMI_SET_BTCOEX_COLOCATED_BT_DEV: ret = ar6000_xioctl_set_btcoex_colocated_bt_dev_cmd(dev, userdata); break; case AR6000_XIOCTL_WMI_SET_BTCOEX_BTINQUIRY_PAGE_CONFIG: ret = ar6000_xioctl_set_btcoex_btinquiry_page_config_cmd(dev, userdata); break; case AR6000_XIOCTL_WMI_SET_BTCOEX_SCO_CONFIG: ret = ar6000_xioctl_set_btcoex_sco_config_cmd( dev, userdata); break; case AR6000_XIOCTL_WMI_SET_BTCOEX_A2DP_CONFIG: ret = ar6000_xioctl_set_btcoex_a2dp_config_cmd(dev, userdata); break; case AR6000_XIOCTL_WMI_SET_BTCOEX_ACLCOEX_CONFIG: ret = ar6000_xioctl_set_btcoex_aclcoex_config_cmd(dev, userdata); break; case AR6000_XIOCTL_WMI_SET_BTCOEX_DEBUG: ret = ar60000_xioctl_set_btcoex_debug_cmd(dev, userdata); break; case AR6000_XIOCTL_WMI_SET_BT_OPERATING_STATUS: ret = ar6000_xioctl_set_btcoex_bt_operating_status_cmd(dev, userdata); break; case AR6000_XIOCTL_WMI_GET_BTCOEX_CONFIG: ret = ar6000_xioctl_get_btcoex_config_cmd(dev, userdata, rq); break; case AR6000_XIOCTL_WMI_GET_BTCOEX_STATS: ret = ar6000_xioctl_get_btcoex_stats_cmd(dev, userdata, rq); break; case AR6000_XIOCTL_WMI_STARTSCAN: { WMI_START_SCAN_CMD setStartScanCmd, *cmdp; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&setStartScanCmd, userdata, sizeof(setStartScanCmd))) { ret = -EFAULT; } else { if (setStartScanCmd.numChannels > 1) { cmdp = A_MALLOC(130); if (copy_from_user(cmdp, userdata, sizeof (*cmdp) + ((setStartScanCmd.numChannels - 1) * sizeof(A_UINT16)))) { kfree(cmdp); ret = -EFAULT; goto ioctl_done; } } else { cmdp = &setStartScanCmd; } if (wmi_startscan_cmd(ar->arWmi, cmdp->scanType, cmdp->forceFgScan, cmdp->isLegacy, cmdp->homeDwellTime, cmdp->forceScanInterval, cmdp->numChannels, cmdp->channelList) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_WMI_SETFIXRATES: { WMI_FIX_RATES_CMD setFixRatesCmd; A_STATUS returnStatus; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&setFixRatesCmd, userdata, sizeof(setFixRatesCmd))) { ret = -EFAULT; } else { returnStatus = wmi_set_fixrates_cmd(ar->arWmi, setFixRatesCmd.fixRateMask); if (returnStatus == A_EINVAL) { ret = -EINVAL; } else if(returnStatus != A_OK) { ret = -EIO; } else { ar->ap_profile_flag = 1; /* There is a change in profile */ } } break; } case AR6000_XIOCTL_WMI_GETFIXRATES: { WMI_FIX_RATES_CMD getFixRatesCmd; AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); int ret = 0; if (ar->bIsDestroyProgress) { ret = -EBUSY; goto ioctl_done; } if (ar->arWmiReady == FALSE) { ret = -EIO; goto ioctl_done; } if (down_interruptible(&ar->arSem)) { ret = -ERESTARTSYS; goto ioctl_done; } if (ar->bIsDestroyProgress) { up(&ar->arSem); ret = -EBUSY; goto ioctl_done; } /* Used copy_from_user/copy_to_user to access user space data */ if (copy_from_user(&getFixRatesCmd, userdata, sizeof(getFixRatesCmd))) { ret = -EFAULT; } else { ar->arRateMask = 0xFFFFFFFF; if (wmi_get_ratemask_cmd(ar->arWmi) != A_OK) { up(&ar->arSem); ret = -EIO; goto ioctl_done; } wait_event_interruptible_timeout(arEvent, ar->arRateMask != 0xFFFFFFFF, wmitimeout * HZ); if (signal_pending(current)) { ret = -EINTR; } if (!ret) { getFixRatesCmd.fixRateMask = ar->arRateMask; } if(copy_to_user(userdata, &getFixRatesCmd, sizeof(getFixRatesCmd))) { ret = -EFAULT; } up(&ar->arSem); } break; } case AR6000_XIOCTL_WMI_SET_AUTHMODE: { WMI_SET_AUTH_MODE_CMD setAuthMode; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&setAuthMode, userdata, sizeof(setAuthMode))) { ret = -EFAULT; } else { if (wmi_set_authmode_cmd(ar->arWmi, setAuthMode.mode) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_WMI_SET_REASSOCMODE: { WMI_SET_REASSOC_MODE_CMD setReassocMode; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&setReassocMode, userdata, sizeof(setReassocMode))) { ret = -EFAULT; } else { if (wmi_set_reassocmode_cmd(ar->arWmi, setReassocMode.mode) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_DIAG_READ: { A_UINT32 addr, data; get_user(addr, (unsigned int *)userdata); addr = TARG_VTOP(ar->arTargetType, addr); if (ar6000_ReadRegDiag(ar->arHifDevice, &addr, &data) != A_OK) { ret = -EIO; } put_user(data, (unsigned int *)userdata + 1); break; } case AR6000_XIOCTL_DIAG_WRITE: { A_UINT32 addr, data; get_user(addr, (unsigned int *)userdata); get_user(data, (unsigned int *)userdata + 1); addr = TARG_VTOP(ar->arTargetType, addr); if (ar6000_WriteRegDiag(ar->arHifDevice, &addr, &data) != A_OK) { ret = -EIO; } break; } case AR6000_XIOCTL_WMI_SET_KEEPALIVE: { WMI_SET_KEEPALIVE_CMD setKeepAlive; if (ar->arWmiReady == FALSE) { ret = -EIO; goto ioctl_done; } else if (copy_from_user(&setKeepAlive, userdata, sizeof(setKeepAlive))){ ret = -EFAULT; } else { if (wmi_set_keepalive_cmd(ar->arWmi, setKeepAlive.keepaliveInterval) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_WMI_SET_PARAMS: { WMI_SET_PARAMS_CMD cmd; if (ar->arWmiReady == FALSE) { ret = -EIO; goto ioctl_done; } else if (copy_from_user(&cmd, userdata, sizeof(cmd))){ ret = -EFAULT; } else if (copy_from_user(&cmd, userdata, sizeof(cmd) + cmd.length)) { ret = -EFAULT; } else { if (wmi_set_params_cmd(ar->arWmi, cmd.opcode, cmd.length, cmd.buffer) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_WMI_SET_MCAST_FILTER: { WMI_SET_MCAST_FILTER_CMD cmd; if (ar->arWmiReady == FALSE) { ret = -EIO; goto ioctl_done; } else if (copy_from_user(&cmd, userdata, sizeof(cmd))){ ret = -EFAULT; } else { if (wmi_set_mcast_filter_cmd(ar->arWmi, cmd.multicast_mac[0], cmd.multicast_mac[1], cmd.multicast_mac[2], cmd.multicast_mac[3]) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_WMI_DEL_MCAST_FILTER: { WMI_SET_MCAST_FILTER_CMD cmd; if (ar->arWmiReady == FALSE) { ret = -EIO; goto ioctl_done; } else if (copy_from_user(&cmd, userdata, sizeof(cmd))){ ret = -EFAULT; } else { if (wmi_del_mcast_filter_cmd(ar->arWmi, cmd.multicast_mac[0], cmd.multicast_mac[1], cmd.multicast_mac[2], cmd.multicast_mac[3]) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_WMI_MCAST_FILTER: { WMI_MCAST_FILTER_CMD cmd; if (ar->arWmiReady == FALSE) { ret = -EIO; goto ioctl_done; } else if (copy_from_user(&cmd, userdata, sizeof(cmd))){ ret = -EFAULT; } else { if (wmi_mcast_filter_cmd(ar->arWmi, cmd.enable) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_WMI_GET_KEEPALIVE: { AR_SOFTC_T *ar = (AR_SOFTC_T *)ar6k_priv(dev); WMI_GET_KEEPALIVE_CMD getKeepAlive; int ret = 0; if (ar->bIsDestroyProgress) { ret =-EBUSY; goto ioctl_done; } if (ar->arWmiReady == FALSE) { ret = -EIO; goto ioctl_done; } if (down_interruptible(&ar->arSem)) { ret = -ERESTARTSYS; goto ioctl_done; } if (ar->bIsDestroyProgress) { up(&ar->arSem); ret = -EBUSY; goto ioctl_done; } if (copy_from_user(&getKeepAlive, userdata,sizeof(getKeepAlive))) { ret = -EFAULT; } else { getKeepAlive.keepaliveInterval = wmi_get_keepalive_cmd(ar->arWmi); ar->arKeepaliveConfigured = 0xFF; if (wmi_get_keepalive_configured(ar->arWmi) != A_OK){ up(&ar->arSem); ret = -EIO; goto ioctl_done; } wait_event_interruptible_timeout(arEvent, ar->arKeepaliveConfigured != 0xFF, wmitimeout * HZ); if (signal_pending(current)) { ret = -EINTR; } if (!ret) { getKeepAlive.configured = ar->arKeepaliveConfigured; } if (copy_to_user(userdata, &getKeepAlive, sizeof(getKeepAlive))) { ret = -EFAULT; } up(&ar->arSem); } break; } case AR6000_XIOCTL_WMI_SET_APPIE: { WMI_SET_APPIE_CMD appIEcmd; A_UINT8 appIeInfo[IEEE80211_APPIE_FRAME_MAX_LEN]; A_UINT32 fType,ieLen; if (ar->arWmiReady == FALSE) { ret = -EIO; goto ioctl_done; } get_user(fType, (A_UINT32 *)userdata); appIEcmd.mgmtFrmType = fType; if (appIEcmd.mgmtFrmType >= IEEE80211_APPIE_NUM_OF_FRAME) { ret = -EIO; } else { get_user(ieLen, (A_UINT32 *)(userdata + 4)); appIEcmd.ieLen = ieLen; A_PRINTF("WPSIE: Type-%d, Len-%d\n",appIEcmd.mgmtFrmType, appIEcmd.ieLen); if (appIEcmd.ieLen > IEEE80211_APPIE_FRAME_MAX_LEN) { ret = -EIO; break; } if (copy_from_user(appIeInfo, userdata + 8, appIEcmd.ieLen)) { ret = -EFAULT; } else { if (wmi_set_appie_cmd(ar->arWmi, appIEcmd.mgmtFrmType, appIEcmd.ieLen, appIeInfo) != A_OK) { ret = -EIO; } } } break; } case AR6000_XIOCTL_WMI_SET_MGMT_FRM_RX_FILTER: { WMI_BSS_FILTER_CMD cmd; A_UINT32 filterType; if (copy_from_user(&filterType, userdata, sizeof(A_UINT32))) { ret = -EFAULT; goto ioctl_done; } if (filterType & (IEEE80211_FILTER_TYPE_BEACON | IEEE80211_FILTER_TYPE_PROBE_RESP)) { cmd.bssFilter = ALL_BSS_FILTER; } else { cmd.bssFilter = NONE_BSS_FILTER; } if (wmi_bssfilter_cmd(ar->arWmi, cmd.bssFilter, 0) != A_OK) { ret = -EIO; } else { ar->arUserBssFilter = cmd.bssFilter; } AR6000_SPIN_LOCK(&ar->arLock, 0); ar->arMgmtFilter = filterType; AR6000_SPIN_UNLOCK(&ar->arLock, 0); break; } case AR6000_XIOCTL_WMI_SET_WSC_STATUS: { A_UINT32 wsc_status; if (ar->arWmiReady == FALSE) { ret = -EIO; goto ioctl_done; } else if (copy_from_user(&wsc_status, userdata, sizeof(A_UINT32))) { ret = -EFAULT; goto ioctl_done; } if (wmi_set_wsc_status_cmd(ar->arWmi, wsc_status) != A_OK) { ret = -EIO; } break; } case AR6000_XIOCTL_BMI_ROMPATCH_INSTALL: { A_UINT32 ROM_addr; A_UINT32 RAM_addr; A_UINT32 nbytes; A_UINT32 do_activate; A_UINT32 rompatch_id; get_user(ROM_addr, (A_UINT32 *)userdata); get_user(RAM_addr, (A_UINT32 *)userdata + 1); get_user(nbytes, (A_UINT32 *)userdata + 2); get_user(do_activate, (A_UINT32 *)userdata + 3); AR_DEBUG_PRINTF(ATH_DEBUG_INFO,("Install rompatch from ROM: 0x%x to RAM: 0x%x length: %d\n", ROM_addr, RAM_addr, nbytes)); ret = BMIrompatchInstall(hifDevice, ROM_addr, RAM_addr, nbytes, do_activate, &rompatch_id); if (ret == A_OK) { put_user(rompatch_id, (unsigned int *)rq->ifr_data); /* return value */ } break; } case AR6000_XIOCTL_BMI_ROMPATCH_UNINSTALL: { A_UINT32 rompatch_id; get_user(rompatch_id, (A_UINT32 *)userdata); AR_DEBUG_PRINTF(ATH_DEBUG_INFO,("UNinstall rompatch_id %d\n", rompatch_id)); ret = BMIrompatchUninstall(hifDevice, rompatch_id); break; } case AR6000_XIOCTL_BMI_ROMPATCH_ACTIVATE: case AR6000_XIOCTL_BMI_ROMPATCH_DEACTIVATE: { A_UINT32 rompatch_count; get_user(rompatch_count, (A_UINT32 *)userdata); AR_DEBUG_PRINTF(ATH_DEBUG_INFO,("Change rompatch activation count=%d\n", rompatch_count)); length = sizeof(A_UINT32) * rompatch_count; if ((buffer = (unsigned char *)A_MALLOC(length)) != NULL) { A_MEMZERO(buffer, length); if (copy_from_user(buffer, &userdata[sizeof(rompatch_count)], length)) { ret = -EFAULT; } else { if (cmd == AR6000_XIOCTL_BMI_ROMPATCH_ACTIVATE) { ret = BMIrompatchActivate(hifDevice, rompatch_count, (A_UINT32 *)buffer); } else { ret = BMIrompatchDeactivate(hifDevice, rompatch_count, (A_UINT32 *)buffer); } } A_FREE(buffer); } else { ret = -ENOMEM; } break; } case AR6000_XIOCTL_SET_IP: { WMI_SET_IP_CMD setIP; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&setIP, userdata, sizeof(setIP))) { ret = -EFAULT; } else { if (wmi_set_ip_cmd(ar->arWmi, &setIP) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_WMI_SET_HOST_SLEEP_MODE: { WMI_SET_HOST_SLEEP_MODE_CMD setHostSleepMode; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&setHostSleepMode, userdata, sizeof(setHostSleepMode))) { ret = -EFAULT; } else { if (wmi_set_host_sleep_mode_cmd(ar->arWmi, &setHostSleepMode) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_WMI_SET_WOW_MODE: { WMI_SET_WOW_MODE_CMD setWowMode; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&setWowMode, userdata, sizeof(setWowMode))) { ret = -EFAULT; } else { if (wmi_set_wow_mode_cmd(ar->arWmi, &setWowMode) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_WMI_GET_WOW_LIST: { WMI_GET_WOW_LIST_CMD getWowList; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&getWowList, userdata, sizeof(getWowList))) { ret = -EFAULT; } else { if (wmi_get_wow_list_cmd(ar->arWmi, &getWowList) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_WMI_ADD_WOW_PATTERN: { #define WOW_PATTERN_SIZE 64 #define WOW_MASK_SIZE 64 WMI_ADD_WOW_PATTERN_CMD cmd; A_UINT8 mask_data[WOW_PATTERN_SIZE]={0}; A_UINT8 pattern_data[WOW_PATTERN_SIZE]={0}; do { if (ar->arWmiReady == FALSE) { ret = -EIO; break; } if(copy_from_user(&cmd, userdata, sizeof(WMI_ADD_WOW_PATTERN_CMD))) { ret = -EFAULT; break; } if (copy_from_user(pattern_data, userdata + 3, cmd.filter_size)) { ret = -EFAULT; break; } if (copy_from_user(mask_data, (userdata + 3 + cmd.filter_size), cmd.filter_size)) { ret = -EFAULT; break; } if (wmi_add_wow_pattern_cmd(ar->arWmi, &cmd, pattern_data, mask_data, cmd.filter_size) != A_OK) { ret = -EIO; } } while(FALSE); #undef WOW_PATTERN_SIZE #undef WOW_MASK_SIZE break; } case AR6000_XIOCTL_WMI_DEL_WOW_PATTERN: { WMI_DEL_WOW_PATTERN_CMD delWowPattern; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&delWowPattern, userdata, sizeof(delWowPattern))) { ret = -EFAULT; } else { if (wmi_del_wow_pattern_cmd(ar->arWmi, &delWowPattern) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_DUMP_HTC_CREDIT_STATE: if (ar->arHtcTarget != NULL) { HTCDumpCreditStates(ar->arHtcTarget); #ifdef HTC_EP_STAT_PROFILING { HTC_ENDPOINT_STATS stats; int i; for (i = 0; i < 5; i++) { if (HTCGetEndpointStatistics(ar->arHtcTarget, i, HTC_EP_STAT_SAMPLE_AND_CLEAR, &stats)) { A_PRINTF(KERN_ALERT"------- Profiling Endpoint : %d \n", i); A_PRINTF(KERN_ALERT"TxCreditLowIndications : %d \n", stats.TxCreditLowIndications); A_PRINTF(KERN_ALERT"TxIssued : %d \n", stats.TxIssued); A_PRINTF(KERN_ALERT"TxDropped: %d \n", stats.TxDropped); A_PRINTF(KERN_ALERT"TxPacketsBundled : %d \n", stats.TxPacketsBundled); A_PRINTF(KERN_ALERT"TxBundles : %d \n", stats.TxBundles); A_PRINTF(KERN_ALERT"TxCreditRpts : %d \n", stats.TxCreditRpts); A_PRINTF(KERN_ALERT"TxCreditsRptsFromRx : %d \n", stats.TxCreditRptsFromRx); A_PRINTF(KERN_ALERT"TxCreditsRptsFromOther : %d \n", stats.TxCreditRptsFromOther); A_PRINTF(KERN_ALERT"TxCreditsRptsFromEp0 : %d \n", stats.TxCreditRptsFromEp0); A_PRINTF(KERN_ALERT"TxCreditsFromRx : %d \n", stats.TxCreditsFromRx); A_PRINTF(KERN_ALERT"TxCreditsFromOther : %d \n", stats.TxCreditsFromOther); A_PRINTF(KERN_ALERT"TxCreditsFromEp0 : %d \n", stats.TxCreditsFromEp0); A_PRINTF(KERN_ALERT"TxCreditsConsummed : %d \n", stats.TxCreditsConsummed); A_PRINTF(KERN_ALERT"TxCreditsReturned : %d \n", stats.TxCreditsReturned); A_PRINTF(KERN_ALERT"RxReceived : %d \n", stats.RxReceived); A_PRINTF(KERN_ALERT"RxPacketsBundled : %d \n", stats.RxPacketsBundled); A_PRINTF(KERN_ALERT"RxLookAheads : %d \n", stats.RxLookAheads); A_PRINTF(KERN_ALERT"RxBundleLookAheads : %d \n", stats.RxBundleLookAheads); A_PRINTF(KERN_ALERT"RxBundleIndFromHdr : %d \n", stats.RxBundleIndFromHdr); A_PRINTF(KERN_ALERT"RxAllocThreshHit : %d \n", stats.RxAllocThreshHit); A_PRINTF(KERN_ALERT"RxAllocThreshBytes : %d \n", stats.RxAllocThreshBytes); A_PRINTF(KERN_ALERT"---- \n"); } } } #endif } break; case AR6000_XIOCTL_TRAFFIC_ACTIVITY_CHANGE: if (ar->arHtcTarget != NULL) { struct ar6000_traffic_activity_change data; if (copy_from_user(&data, userdata, sizeof(data))) { ret = -EFAULT; goto ioctl_done; } /* note, this is used for testing (mbox ping testing), indicate activity * change using the stream ID as the traffic class */ ar6000_indicate_tx_activity(ar, (A_UINT8)data.StreamID, data.Active ? TRUE : FALSE); } break; case AR6000_XIOCTL_WMI_SET_CONNECT_CTRL_FLAGS: if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&connectCtrlFlags, userdata, sizeof(connectCtrlFlags))) { ret = -EFAULT; } else { ar->arConnectCtrlFlags = connectCtrlFlags; } break; case AR6000_XIOCTL_WMI_SET_AKMP_PARAMS: if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&akmpParams, userdata, sizeof(WMI_SET_AKMP_PARAMS_CMD))) { ret = -EFAULT; } else { if (wmi_set_akmp_params_cmd(ar->arWmi, &akmpParams) != A_OK) { ret = -EIO; } } break; case AR6000_XIOCTL_WMI_SET_PMKID_LIST: if (ar->arWmiReady == FALSE) { ret = -EIO; } else { if (copy_from_user(&pmkidInfo.numPMKID, userdata, sizeof(pmkidInfo.numPMKID))) { ret = -EFAULT; break; } if (copy_from_user(&pmkidInfo.pmkidList, userdata + sizeof(pmkidInfo.numPMKID), pmkidInfo.numPMKID * sizeof(WMI_PMKID))) { ret = -EFAULT; break; } if (wmi_set_pmkid_list_cmd(ar->arWmi, &pmkidInfo) != A_OK) { ret = -EIO; } } break; case AR6000_XIOCTL_WMI_GET_PMKID_LIST: if (ar->arWmiReady == FALSE) { ret = -EIO; } else { if (wmi_get_pmkid_list_cmd(ar->arWmi) != A_OK) { ret = -EIO; } } break; case AR6000_XIOCTL_WMI_ABORT_SCAN: if (ar->arWmiReady == FALSE) { ret = -EIO; } ret = wmi_abort_scan_cmd(ar->arWmi); break; case AR6000_XIOCTL_AP_HIDDEN_SSID: { A_UINT8 hidden_ssid; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&hidden_ssid, userdata, sizeof(hidden_ssid))) { ret = -EFAULT; } else { wmi_ap_set_hidden_ssid(ar->arWmi, hidden_ssid); ar->ap_hidden_ssid = hidden_ssid; ar->ap_profile_flag = 1; /* There is a change in profile */ } break; } case AR6000_XIOCTL_AP_GET_STA_LIST: { if (ar->arWmiReady == FALSE) { ret = -EIO; } else { A_UINT8 i; ap_get_sta_t temp; A_MEMZERO(&temp, sizeof(temp)); for(i=0;ista_list[i].mac, ATH_MAC_LEN); temp.sta[i].aid = ar->sta_list[i].aid; temp.sta[i].keymgmt = ar->sta_list[i].keymgmt; temp.sta[i].ucipher = ar->sta_list[i].ucipher; temp.sta[i].auth = ar->sta_list[i].auth; } if(copy_to_user((ap_get_sta_t *)rq->ifr_data, &temp, sizeof(ar->sta_list))) { ret = -EFAULT; } } break; } case AR6000_XIOCTL_AP_SET_NUM_STA: { A_UINT8 num_sta; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&num_sta, userdata, sizeof(num_sta))) { ret = -EFAULT; } else if(num_sta > AP_MAX_NUM_STA) { /* value out of range */ ret = -EINVAL; } else { wmi_ap_set_num_sta(ar->arWmi, num_sta); } break; } case AR6000_XIOCTL_AP_SET_ACL_POLICY: { A_UINT8 policy; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&policy, userdata, sizeof(policy))) { ret = -EFAULT; } else if(policy == ar->g_acl.policy) { /* No change in policy */ } else { if(!(policy & AP_ACL_RETAIN_LIST_MASK)) { /* clear ACL list */ memset(&ar->g_acl,0,sizeof(WMI_AP_ACL)); } ar->g_acl.policy = policy; wmi_ap_set_acl_policy(ar->arWmi, policy); } break; } case AR6000_XIOCTL_AP_SET_ACL_MAC: { WMI_AP_ACL_MAC_CMD acl; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&acl, userdata, sizeof(acl))) { ret = -EFAULT; } else { if(acl_add_del_mac(&ar->g_acl, &acl)) { wmi_ap_acl_mac_list(ar->arWmi, &acl); } else { A_PRINTF("ACL list error\n"); ret = -EIO; } } break; } case AR6000_XIOCTL_AP_GET_ACL_LIST: { if (ar->arWmiReady == FALSE) { ret = -EIO; } else if(copy_to_user((WMI_AP_ACL *)rq->ifr_data, &ar->g_acl, sizeof(WMI_AP_ACL))) { ret = -EFAULT; } break; } case AR6000_XIOCTL_AP_COMMIT_CONFIG: { ret = ar6000_ap_mode_profile_commit(ar); break; } case IEEE80211_IOCTL_GETWPAIE: { struct ieee80211req_wpaie wpaie; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&wpaie, userdata, sizeof(wpaie))) { ret = -EFAULT; } else if (ar6000_ap_mode_get_wpa_ie(ar, &wpaie)) { ret = -EFAULT; } else if(copy_to_user(userdata, &wpaie, sizeof(wpaie))) { ret = -EFAULT; } break; } case AR6000_XIOCTL_AP_CONN_INACT_TIME: { A_UINT32 period; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&period, userdata, sizeof(period))) { ret = -EFAULT; } else { wmi_ap_conn_inact_time(ar->arWmi, period); } break; } case AR6000_XIOCTL_AP_PROT_SCAN_TIME: { WMI_AP_PROT_SCAN_TIME_CMD bgscan; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&bgscan, userdata, sizeof(bgscan))) { ret = -EFAULT; } else { wmi_ap_bgscan_time(ar->arWmi, bgscan.period_min, bgscan.dwell_ms); } break; } case AR6000_XIOCTL_AP_SET_COUNTRY: { ret = ar6000_ioctl_set_country(dev, rq); break; } case AR6000_XIOCTL_AP_SET_DTIM: { WMI_AP_SET_DTIM_CMD d; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&d, userdata, sizeof(d))) { ret = -EFAULT; } else { if(d.dtim > 0 && d.dtim < 11) { ar->ap_dtim_period = d.dtim; wmi_ap_set_dtim(ar->arWmi, d.dtim); ar->ap_profile_flag = 1; /* There is a change in profile */ } else { A_PRINTF("DTIM out of range. Valid range is [1-10]\n"); ret = -EIO; } } break; } case AR6000_XIOCTL_WMI_TARGET_EVENT_REPORT: { WMI_SET_TARGET_EVENT_REPORT_CMD evtCfgCmd; if (ar->arWmiReady == FALSE) { ret = -EIO; } if (copy_from_user(&evtCfgCmd, userdata, sizeof(evtCfgCmd))) { ret = -EFAULT; break; } ret = wmi_set_target_event_report_cmd(ar->arWmi, &evtCfgCmd); break; } case AR6000_XIOCTL_AP_INTRA_BSS_COMM: { A_UINT8 intra=0; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&intra, userdata, sizeof(intra))) { ret = -EFAULT; } else { ar->intra_bss = (intra?1:0); } break; } case AR6000_XIOCTL_DUMP_MODULE_DEBUG_INFO: { struct drv_debug_module_s moduleinfo; if (copy_from_user(&moduleinfo, userdata, sizeof(moduleinfo))) { ret = -EFAULT; break; } a_dump_module_debug_info_by_name(moduleinfo.modulename); ret = 0; break; } case AR6000_XIOCTL_MODULE_DEBUG_SET_MASK: { struct drv_debug_module_s moduleinfo; if (copy_from_user(&moduleinfo, userdata, sizeof(moduleinfo))) { ret = -EFAULT; break; } if (A_FAILED(a_set_module_mask(moduleinfo.modulename, moduleinfo.mask))) { ret = -EFAULT; } break; } case AR6000_XIOCTL_MODULE_DEBUG_GET_MASK: { struct drv_debug_module_s moduleinfo; if (copy_from_user(&moduleinfo, userdata, sizeof(moduleinfo))) { ret = -EFAULT; break; } if (A_FAILED(a_get_module_mask(moduleinfo.modulename, &moduleinfo.mask))) { ret = -EFAULT; break; } if (copy_to_user(userdata, &moduleinfo, sizeof(moduleinfo))) { ret = -EFAULT; break; } break; } #ifdef ATH_AR6K_11N_SUPPORT case AR6000_XIOCTL_DUMP_RCV_AGGR_STATS: { PACKET_LOG *copy_of_pkt_log; aggr_dump_stats(ar->aggr_cntxt, ©_of_pkt_log); if (copy_to_user(rq->ifr_data, copy_of_pkt_log, sizeof(PACKET_LOG))) { ret = -EFAULT; } break; } case AR6000_XIOCTL_SETUP_AGGR: { WMI_ADDBA_REQ_CMD cmd; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&cmd, userdata, sizeof(cmd))) { ret = -EFAULT; } else { wmi_setup_aggr_cmd(ar->arWmi, cmd.tid); } } break; case AR6000_XIOCTL_DELE_AGGR: { WMI_DELBA_REQ_CMD cmd; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&cmd, userdata, sizeof(cmd))) { ret = -EFAULT; } else { wmi_delete_aggr_cmd(ar->arWmi, cmd.tid, cmd.is_sender_initiator); } } break; case AR6000_XIOCTL_ALLOW_AGGR: { WMI_ALLOW_AGGR_CMD cmd; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&cmd, userdata, sizeof(cmd))) { ret = -EFAULT; } else { wmi_allow_aggr_cmd(ar->arWmi, cmd.tx_allow_aggr, cmd.rx_allow_aggr); } } break; case AR6000_XIOCTL_SET_HT_CAP: { if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&htCap, userdata, sizeof(htCap))) { ret = -EFAULT; } else { if (wmi_set_ht_cap_cmd(ar->arWmi, &htCap) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_SET_HT_OP: { if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&htOp, userdata, sizeof(htOp))) { ret = -EFAULT; } else { if (wmi_set_ht_op_cmd(ar->arWmi, htOp.sta_chan_width) != A_OK) { ret = -EIO; } } break; } #endif case AR6000_XIOCTL_ACL_DATA: { void *osbuf = NULL; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (ar6000_create_acl_data_osbuf(dev, (A_UINT8*)userdata, &osbuf) != A_OK) { ret = -EIO; } else { if (wmi_data_hdr_add(ar->arWmi, osbuf, DATA_MSGTYPE, 0, WMI_DATA_HDR_DATA_TYPE_ACL,0,NULL) != A_OK) { AR_DEBUG_PRINTF(ATH_DEBUG_ERR,("XIOCTL_ACL_DATA - wmi_data_hdr_add failed\n")); } else { /* Send data buffer over HTC */ ar6000_acl_data_tx(osbuf, ar->arNetDev); } } break; } case AR6000_XIOCTL_HCI_CMD: { char tmp_buf[512]; A_INT8 i; WMI_HCI_CMD *cmd = (WMI_HCI_CMD *)tmp_buf; A_UINT8 size; size = sizeof(cmd->cmd_buf_sz); if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(cmd, userdata, size)) { ret = -EFAULT; } else if(copy_from_user(cmd->buf, userdata + size, cmd->cmd_buf_sz)) { ret = -EFAULT; } else { if (wmi_send_hci_cmd(ar->arWmi, cmd->buf, cmd->cmd_buf_sz) != A_OK) { ret = -EIO; }else if(loghci) { A_PRINTF_LOG("HCI Command To PAL --> \n"); for(i = 0; i < cmd->cmd_buf_sz; i++) { A_PRINTF_LOG("0x%02x ",cmd->buf[i]); if((i % 10) == 0) { A_PRINTF_LOG("\n"); } } A_PRINTF_LOG("\n"); A_PRINTF_LOG("==================================\n"); } } break; } case AR6000_XIOCTL_WLAN_CONN_PRECEDENCE: { WMI_SET_BT_WLAN_CONN_PRECEDENCE cmd; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&cmd, userdata, sizeof(cmd))) { ret = -EFAULT; } else { if (cmd.precedence == BT_WLAN_CONN_PRECDENCE_WLAN || cmd.precedence == BT_WLAN_CONN_PRECDENCE_PAL) { if ( wmi_set_wlan_conn_precedence_cmd(ar->arWmi, cmd.precedence) != A_OK) { ret = -EIO; } } else { ret = -EINVAL; } } break; } case AR6000_XIOCTL_AP_GET_STAT: { ret = ar6000_ioctl_get_ap_stats(dev, rq); break; } case AR6000_XIOCTL_SET_TX_SELECT_RATES: { WMI_SET_TX_SELECT_RATES_CMD masks; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&masks, userdata, sizeof(masks))) { ret = -EFAULT; } else { if (wmi_set_tx_select_rates_cmd(ar->arWmi, masks.rateMasks) != A_OK) { ret = -EIO; } } break; } case AR6000_XIOCTL_AP_GET_HIDDEN_SSID: { WMI_AP_HIDDEN_SSID_CMD ssid; ssid.hidden_ssid = ar->ap_hidden_ssid; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if(copy_to_user((WMI_AP_HIDDEN_SSID_CMD *)rq->ifr_data, &ssid, sizeof(WMI_AP_HIDDEN_SSID_CMD))) { ret = -EFAULT; } break; } case AR6000_XIOCTL_AP_GET_COUNTRY: { WMI_AP_SET_COUNTRY_CMD cty; A_MEMCPY(cty.countryCode, ar->ap_country_code, 3); if (ar->arWmiReady == FALSE) { ret = -EIO; } else if(copy_to_user((WMI_AP_SET_COUNTRY_CMD *)rq->ifr_data, &cty, sizeof(WMI_AP_SET_COUNTRY_CMD))) { ret = -EFAULT; } break; } case AR6000_XIOCTL_AP_GET_WMODE: { if (ar->arWmiReady == FALSE) { ret = -EIO; } else if(copy_to_user((A_UINT8 *)rq->ifr_data, &ar->ap_wmode, sizeof(A_UINT8))) { ret = -EFAULT; } break; } case AR6000_XIOCTL_AP_GET_DTIM: { WMI_AP_SET_DTIM_CMD dtim; dtim.dtim = ar->ap_dtim_period; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if(copy_to_user((WMI_AP_SET_DTIM_CMD *)rq->ifr_data, &dtim, sizeof(WMI_AP_SET_DTIM_CMD))) { ret = -EFAULT; } break; } case AR6000_XIOCTL_AP_GET_BINTVL: { WMI_BEACON_INT_CMD bi; bi.beaconInterval = ar->ap_beacon_interval; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if(copy_to_user((WMI_BEACON_INT_CMD *)rq->ifr_data, &bi, sizeof(WMI_BEACON_INT_CMD))) { ret = -EFAULT; } break; } case AR6000_XIOCTL_AP_GET_RTS: { WMI_SET_RTS_CMD rts; rts.threshold = ar->arRTS; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if(copy_to_user((WMI_SET_RTS_CMD *)rq->ifr_data, &rts, sizeof(WMI_SET_RTS_CMD))) { ret = -EFAULT; } break; } case AR6000_XIOCTL_FETCH_TARGET_REGS: { A_UINT32 targregs[AR6003_FETCH_TARG_REGS_COUNT]; if (ar->arTargetType == TARGET_TYPE_AR6003) { ar6k_FetchTargetRegs(hifDevice, targregs); if (copy_to_user((A_UINT32 *)rq->ifr_data, &targregs, sizeof(targregs))) { ret = -EFAULT; } } else { ret = -EOPNOTSUPP; } break; } case AR6000_XIOCTL_AP_SET_11BG_RATESET: { WMI_AP_SET_11BG_RATESET_CMD rate; if (ar->arWmiReady == FALSE) { ret = -EIO; } else if (copy_from_user(&rate, userdata, sizeof(rate))) { ret = -EFAULT; } else { wmi_ap_set_rateset(ar->arWmi, rate.rateset); } break; } default: ret = -EOPNOTSUPP; } ioctl_done: rtnl_lock(); /* restore rtnl state */ dev_put(dev); return ret; } A_UINT8 mac_cmp_wild(A_UINT8 *mac, A_UINT8 *new_mac, A_UINT8 wild, A_UINT8 new_wild) { A_UINT8 i; for(i=0;i=0;i--) { if(mac_cmp_wild(a->acl_mac[i], acl->mac, a->wildcard[i], acl->wildcard)==0) already_avail = i; if(!((1 << i) & a->index)) free_slot = i; } if(acl->action == ADD_MAC_ADDR) { /* Dont add mac if it is already available */ if((already_avail >= 0) || (free_slot == -1)) return 0; A_MEMCPY(a->acl_mac[free_slot], acl->mac, ATH_MAC_LEN); a->index = a->index | (1 << free_slot); acl->index = free_slot; a->wildcard[free_slot] = acl->wildcard; return 1; } else if(acl->action == DEL_MAC_ADDR) { if(acl->index > AP_ACL_SIZE) return 0; if(!(a->index & (1 << acl->index))) return 0; A_MEMZERO(a->acl_mac[acl->index],ATH_MAC_LEN); a->index = a->index & ~(1 << acl->index); a->wildcard[acl->index] = 0; return 1; } return 0; }