mwifiex/mwifiex_8997/mapp/mlanutl/mlanutl.c
Fugang Duan bd8827d169 mwifiex: 8997: add W16.68.10.p16 release sdk
The sdk release is from NXP offial web:
https://www.nxp.com/products/wireless/wi-fi-plus-bluetooth/
88w8997-wi-fi-dual-band-with-bluetooth-5-for-a-v-streaming-and-digital-tv:88W8997?tab=Design_Tools_Tab

The release file is:
PCIE-WLAN-UART-BT-8997-U16-X86-W16.68.10.p16-16.26.10.p16-C4X16640_V4-MGPL

The sdk version is: W16.68.10.p16

Signed-off-by: Fugang Duan <fugang.duan@nxp.com>
2020-01-13 10:35:39 +08:00

18720 lines
473 KiB
C
Executable file

/** @file mlanutl.c
*
* @brief Program to control parameters in the mlandriver
*
* Copyright (C) 2011-2019, Marvell International Ltd.
*
* This software file (the "File") is distributed by Marvell International
* Ltd. under the terms of the GNU General Public License Version 2, June 1991
* (the "License"). You may use, redistribute and/or modify this File in
* accordance with the terms and conditions of the License, a copy of which
* is available by writing to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA or on the
* worldwide web at http://www.gnu.org/licenses/old-licenses/gpl-2.0.txt.
*
* THE FILE IS DISTRIBUTED AS-IS, WITHOUT WARRANTY OF ANY KIND, AND THE
* IMPLIED WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE
* ARE EXPRESSLY DISCLAIMED. The License provides additional details about
* this warranty disclaimer.
*
*/
/************************************************************************
Change log:
11/04/2011: initial version
************************************************************************/
#include <stdio.h>
#include <stdlib.h>
#include <unistd.h>
#include <string.h>
#include <ctype.h>
#include <signal.h>
#include <time.h>
#include <sys/time.h>
#include <getopt.h>
#include <sys/socket.h>
#include <linux/netlink.h>
#include <linux/if.h>
#include "mlanutl.h"
/** Supported stream modes */
#define HT_STREAM_MODE_1X1 0x11
#define HT_STREAM_MODE_2X2 0x22
/** mlanutl version number */
#define MLANUTL_VER "M1.3"
/** Initial number of total private ioctl calls */
#define IW_INIT_PRIV_NUM 128
/** Maximum number of total private ioctl calls supported */
#define IW_MAX_PRIV_NUM 1024
/** Termination flag */
int terminate_flag = 0;
typedef struct {
t_u8 chanNum; /**< Channel Number */
t_u8 chanLoad; /**< Channel Load fraction */
t_s16 anpi; /**< Channel ANPI */
} ChanRptInfo_t;
/********************************************************
Local Variables
********************************************************/
#define BAND_B (1U << 0)
#define BAND_G (1U << 1)
#define BAND_A (1U << 2)
#define BAND_GN (1U << 3)
#define BAND_AN (1U << 4)
#define BAND_GAC (1U << 5)
#define BAND_AAC (1U << 6)
static char *band[] = {
"B",
"G",
"A",
"GN",
"AN",
"GAC",
"AAC",
};
/** Stringification of rateId enumeration */
const char *rateIdStr[] = { "1", "2", "5.5", "11", "--",
"6", "9", "12", "18", "24", "36", "48", "54", "--",
"M0", "M1", "M2", "M3", "M4", "M5", "M6", "M7",
"H0", "H1", "H2", "H3", "H4", "H5", "H6", "H7"
};
#ifdef DEBUG_LEVEL1
#define MMSG MBIT(0)
#define MFATAL MBIT(1)
#define MERROR MBIT(2)
#define MDATA MBIT(3)
#define MCMND MBIT(4)
#define MEVENT MBIT(5)
#define MINTR MBIT(6)
#define MIOCTL MBIT(7)
#define MMPA_D MBIT(15)
#define MDAT_D MBIT(16)
#define MCMD_D MBIT(17)
#define MEVT_D MBIT(18)
#define MFW_D MBIT(19)
#define MIF_D MBIT(20)
#define MENTRY MBIT(28)
#define MWARN MBIT(29)
#define MINFO MBIT(30)
#define MHEX_DUMP MBIT(31)
#endif
static int process_multi_chan_cfg(int argc, char *argv[]);
static int process_multi_chan_policy(int argc, char *argv[]);
static int process_drcs_time_slicing_cfg(int argc, char *argv[]);
static int process_dot11_txrx(int argc, char *argv[]);
#ifdef RX_PACKET_COALESCE
static int process_rx_pkt_coalesce_cfg(int argc, char *argv[]);
static void print_rx_packet_coalesc_help(void);
#endif
static int process_version(int argc, char *argv[]);
static int process_bandcfg(int argc, char *argv[]);
static int process_hostcmd(int argc, char *argv[]);
static int process_httxcfg(int argc, char *argv[]);
static int process_htcapinfo(int argc, char *argv[]);
static int process_addbapara(int argc, char *argv[]);
static int process_aggrpriotbl(int argc, char *argv[]);
static int process_addbareject(int argc, char *argv[]);
static int process_delba(int argc, char *argv[]);
static int process_rejectaddbareq(int argc, char *argv[]);
static int process_vhtcfg(int argc, char *argv[]);
static int process_opermodecfg(int argc, char *argv[]);
static int process_datarate(int argc, char *argv[]);
static int process_txratecfg(int argc, char *argv[]);
static int process_getlog(int argc, char *argv[]);
static int process_esuppmode(int argc, char *argv[]);
static int process_passphrase(int argc, char *argv[]);
static int process_deauth(int argc, char *argv[]);
#ifdef UAP_SUPPORT
static int process_getstalist(int argc, char *argv[]);
#endif
#if defined(WIFI_DIRECT_SUPPORT)
#if defined(STA_SUPPORT) && defined(UAP_SUPPORT)
static int process_bssrole(int argc, char *argv[]);
#endif
#endif
#ifdef STA_SUPPORT
static int process_setuserscan(int argc, char *argv[]);
static int wlan_process_getscantable(int argc, char *argv[],
wlan_ioctl_user_scan_cfg *scan_req);
static int process_getscantable(int argc, char *argv[]);
static int process_extcapcfg(int argc, char *argv[]);
static int process_cancelscan(int argc, char *argv[]);
#endif
static int process_deepsleep(int argc, char *argv[]);
static int process_ipaddr(int argc, char *argv[]);
static int process_otpuserdata(int argc, char *argv[]);
static int process_countrycode(int argc, char *argv[]);
static int process_tcpackenh(int argc, char *argv[]);
#ifdef REASSOCIATION
static int process_assocessid(int argc, char *argv[]);
#endif
#ifdef STA_SUPPORT
static int process_listeninterval(int argc, char *argv[]);
static int process_psmode(int argc, char *argv[]);
#endif
#ifdef DEBUG_LEVEL1
static int process_drvdbg(int argc, char *argv[]);
#endif
static int process_hscfg(int argc, char *argv[]);
static int process_hssetpara(int argc, char *argv[]);
static int process_wakeupresaon(int argc, char *argv[]);
static int process_mgmtfilter(int argc, char *argv[]);
static int process_scancfg(int argc, char *argv[]);
static int process_warmreset(int argc, char *argv[]);
static int process_txpowercfg(int argc, char *argv[]);
static int process_pscfg(int argc, char *argv[]);
static int process_bcntimeoutcfg(int argc, char *argv[]);
static int process_sleeppd(int argc, char *argv[]);
static int process_txcontrol(int argc, char *argv[]);
static int process_host_tdls_config(int argc, char *argv[]);
static int process_tdls_config(int argc, char *argv[]);
static int process_tdls_setinfo(int argc, char *argv[]);
static int process_tdls_discovery(int argc, char *argv[]);
static int process_tdls_setup(int argc, char *argv[]);
static int process_tdls_teardown(int argc, char *argv[]);
static int process_tdls_powermode(int argc, char *argv[]);
static int process_tdls_link_status(int argc, char *argv[]);
static int process_tdls_debug(int argc, char *argv[]);
static int process_tdls_channel_switch(int argc, char *argv[]);
static int process_tdls_stop_channel_switch(int argc, char *argv[]);
static int process_tdls_cs_params(int argc, char *argv[]);
static int process_tdls_disable_channel_switch(int argc, char *argv[]);
static int process_tdls_idle_time(int argc, char *argv[]);
static int process_dfs_offload_enable(int argc, char *argv[]);
static int process_customie(int argc, char *argv[]);
static int process_regrdwr(int argc, char *argv[]);
static int process_rdeeprom(int argc, char *argv[]);
static int process_memrdwr(int argc, char *argv[]);
static int process_mefcfg(int argc, char *argv[]);
#ifdef STA_SUPPORT
static int process_arpfilter(int argc, char *argv[]);
#endif
static int process_cfgdata(int argc, char *argv[]);
static int process_mgmtframetx(int argc, char *argv[]);
static int process_mgmt_frame_passthrough(int argc, char *argv[]);
static int process_qconfig(int argc, char *argv[]);
static int process_addts(int argc, char *argv[]);
static int process_delts(int argc, char *argv[]);
static int process_wmm_qstatus(int argc, char *argv[]);
static int process_wmm_ts_status(int argc, char *argv[]);
static int process_qos_config(int argc, char *argv[]);
static int process_macctrl(int argc, char *argv[]);
static int process_fwmacaddr(int argc, char *argv[]);
static int process_regioncode(int argc, char *argv[]);
static int process_cfpinfo(int argc, char *argv[]);
static int process_offchannel(int argc, char *argv[]);
static int process_linkstats(int argc, char *argv[]);
#if defined(STA_SUPPORT)
static int process_pmfcfg(int argc, char *argv[]);
#endif
static int process_verext(int argc, char *argv[]);
#if defined(STA_SUPPORT) && defined(STA_WEXT)
static int process_radio_ctrl(int argc, char *argv[]);
#endif
static int process_wmm_cfg(int argc, char *argv[]);
static int process_wmm_param_config(int argc, char *argv[]);
#if defined(STA_SUPPORT)
static int process_11d_cfg(int argc, char *argv[]);
static int process_11d_clr_tbl(int argc, char *argv[]);
#endif
static int process_wws_cfg(int argc, char *argv[]);
#if defined(REASSOCIATION)
static int process_set_get_reassoc(int argc, char *argv[]);
#endif
static int process_txbuf_cfg(int argc, char *argv[]);
#ifdef STA_SUPPORT
static int process_set_get_auth_type(int argc, char *argv[]);
#endif
static int process_11h_local_pwr_constraint(int argc, char *argv[]);
static int process_ht_stream_cfg(int argc, char *argv[]);
static int process_mimo_switch(int argc, char *argv[]);
static int process_thermal(int argc, char *argv[]);
static int process_beacon_interval(int argc, char *argv[]);
static int process_cwmode(int argc, char *argv[]);
#ifdef STA_SUPPORT
static int process_get_signal(int argc, char *argv[]);
static int process_get_signal_ext(int argc, char *argv[]);
static int process_signalext_cfg(int argc, char *argv[]);
#endif
static int process_inactivity_timeout_ext(int argc, char *argv[]);
static int process_11n_amsdu_aggr_ctrl(int argc, char *argv[]);
static int process_tx_bf_cap_ioctl(int argc, char *argv[]);
static int process_sleep_params(int argc, char *argv[]);
static int process_net_monitor(int argc, char *argv[]);
#if defined(DFS_TESTING_SUPPORT)
static int process_dfs_testing(int argc, char *argv[]);
#endif
static int process_cfp_code(int argc, char *argv[]);
static int process_set_get_tx_rx_ant(int argc, char *argv[]);
static int process_sysclock(int argc, char *argv[]);
static int process_associate_ssid_bssid(int argc, char *argv[]);
static int process_tx_bf_cfg(int argc, char *argv[]);
static int process_wps_cfg(int argc, char *argv[]);
static int process_port_ctrl(int argc, char *argv[]);
static int process_bypassed_packet(int argc, char *argv[]);
/* #ifdef FW_WAKEUP_METHOD */
static int process_fw_wakeup_method(int argc, char *argv[]);
/* #endif */
#if defined(WIFI_DIRECT_SUPPORT)
static int process_cfg_noa_opp_ps(int argc, char *argv[]);
#endif
static int process_dscpmap(int argc, char *argv[]);
#ifdef WIFI_DIRECT_SUPPORT
static int process_miracastcfg(int argc, char *argv[]);
#endif
static int process_coex_rx_winsize(int argc, char *argv[]);
static int process_dfs_repeater(int argc, char *argv[]);
static int process_txaggrctrl(int argc, char *argv[]);
static int process_auto_tdls(int argc, char *argv[]);
static int process_pcie_reg_rw(int argc, char *argv[]);
static int process_pcie_bar0_reg_rw(int argc, char *argv[]);
static int process_get_sensor_temp(int argc, char *argv[]);
static int process_chan_graph(int argc, char *argv[]);
static int process_11k_cfg(int argc, char *argv[]);
static int process_11k_neighbor_report(int argc, char *argv[]);
static int process_extend_channel_switch(int argc, char *argv[]);
static int process_auto_arp(int argc, char *argv[]);
static int process_txrxhistogram(int argc, char *argv[]);
static int process_per_pkt_cfg(int argc, char *argv[]);
static int process_ind_rst_cfg(int argc, char *argv[]);
int process_tsf(int argc, char *argv[]);
static int process_dyn_bw(int argc, char *argv[]);
static int process_tx_ampdu_prot_mode(int argc, char *argv[]);
static int process_ctrldeauth(int argc, char *argv[]);
static int process_robustcoex(int argc, char *argv[]);
static int process_acs(int argc, char *argv[]);
static int process_bootsleep(int argc, char *argv[]);
struct command_node command_list[] = {
{"version", process_version},
{"bandcfg", process_bandcfg},
{"hostcmd", process_hostcmd},
{"httxcfg", process_httxcfg},
{"htcapinfo", process_htcapinfo},
{"addbapara", process_addbapara},
{"aggrpriotbl", process_aggrpriotbl},
{"addbareject", process_addbareject},
{"delba", process_delba},
{"rejectaddbareq", process_rejectaddbareq},
{"vhtcfg", process_vhtcfg},
{"opermodecfg", process_opermodecfg},
{"getdatarate", process_datarate},
{"txratecfg", process_txratecfg},
{"getlog", process_getlog},
{"esuppmode", process_esuppmode},
{"passphrase", process_passphrase},
{"deauth", process_deauth},
#ifdef UAP_SUPPORT
{"getstalist", process_getstalist},
#endif
#if defined(WIFI_DIRECT_SUPPORT)
#if defined(STA_SUPPORT) && defined(UAP_SUPPORT)
{"bssrole", process_bssrole},
#endif
#endif
#ifdef STA_SUPPORT
{"setuserscan", process_setuserscan},
{"getscantable", process_getscantable},
{"extcapcfg", process_extcapcfg},
{"cancelscan", process_cancelscan},
#endif
{"deepsleep", process_deepsleep},
{"ipaddr", process_ipaddr},
{"otpuserdata", process_otpuserdata},
{"countrycode", process_countrycode},
{"tcpackenh", process_tcpackenh},
#ifdef REASSOCIATION
{"assocessid", process_assocessid},
{"assocessid_bssid", process_assocessid},
#endif
#ifdef STA_SUPPORT
{"listeninterval", process_listeninterval},
{"psmode", process_psmode},
#endif
#ifdef DEBUG_LEVEL1
{"drvdbg", process_drvdbg},
#endif
{"hscfg", process_hscfg},
{"hssetpara", process_hssetpara},
{"wakeupreason", process_wakeupresaon},
{"mgmtfilter", process_mgmtfilter},
{"scancfg", process_scancfg},
{"warmreset", process_warmreset},
{"txpowercfg", process_txpowercfg},
{"pscfg", process_pscfg},
{"bcntimeoutcfg", process_bcntimeoutcfg},
{"sleeppd", process_sleeppd},
{"txcontrol", process_txcontrol},
{"host_tdls_config", process_host_tdls_config},
{"tdls_config", process_tdls_config},
{"tdls_setinfo", process_tdls_setinfo},
{"tdls_discovery", process_tdls_discovery},
{"tdls_setup", process_tdls_setup},
{"tdls_teardown", process_tdls_teardown},
{"tdls_powermode", process_tdls_powermode},
{"tdls_link_status", process_tdls_link_status},
{"tdls_debug", process_tdls_debug},
{"tdls_channel_switch", process_tdls_channel_switch},
{"tdls_stop_channel_switch", process_tdls_stop_channel_switch},
{"tdls_cs_params", process_tdls_cs_params},
{"tdls_disable_cs", process_tdls_disable_channel_switch},
{"tdls_idle_time", process_tdls_idle_time},
{"dfs_offload", process_dfs_offload_enable},
{"customie", process_customie},
{"regrdwr", process_regrdwr},
{"rdeeprom", process_rdeeprom},
{"memrdwr", process_memrdwr},
{"mefcfg", process_mefcfg},
#ifdef STA_SUPPORT
{"arpfilter", process_arpfilter},
#endif
{"cfgdata", process_cfgdata},
{"mgmtframetx", process_mgmtframetx},
{"mgmtframectrl", process_mgmt_frame_passthrough},
{"qconfig", process_qconfig},
{"addts", process_addts},
{"delts", process_delts},
{"ts_status", process_wmm_ts_status},
{"qstatus", process_wmm_qstatus},
{"qoscfg", process_qos_config},
{"macctrl", process_macctrl},
{"fwmacaddr", process_fwmacaddr},
{"regioncode", process_regioncode},
{"cfpinfo", process_cfpinfo},
{"offchannel", process_offchannel},
{"linkstats", process_linkstats},
#if defined(STA_SUPPORT)
{"pmfcfg", process_pmfcfg},
#endif
{"verext", process_verext},
#if defined(STA_SUPPORT) && defined(STA_WEXT)
{"radioctrl", process_radio_ctrl},
#endif
{"wmmcfg", process_wmm_cfg},
{"wmmparamcfg", process_wmm_param_config},
#if defined(STA_SUPPORT)
{"11dcfg", process_11d_cfg},
{"11dclrtbl", process_11d_clr_tbl},
#endif
{"wwscfg", process_wws_cfg},
#if defined(REASSOCIATION)
{"reassoctrl", process_set_get_reassoc},
#endif
{"txbufcfg", process_txbuf_cfg},
#ifdef STA_SUPPORT
{"authtype", process_set_get_auth_type},
#endif
{"powercons", process_11h_local_pwr_constraint},
{"htstreamcfg", process_ht_stream_cfg},
{"mimoswitch", process_mimo_switch},
{"thermal", process_thermal},
{"bcninterval", process_beacon_interval},
{"cwmode", process_cwmode},
#ifdef STA_SUPPORT
{"getsignal", process_get_signal},
{"getsignalext", process_get_signal_ext},
{"getsignalextv2", process_get_signal_ext},
{"signalextcfg", process_signalext_cfg},
#endif
{"inactivityto", process_inactivity_timeout_ext},
{"amsduaggrctrl", process_11n_amsdu_aggr_ctrl},
{"httxbfcap", process_tx_bf_cap_ioctl},
{"sleepparams", process_sleep_params},
{"netmon", process_net_monitor},
#if defined(DFS_TESTING_SUPPORT)
{"dfstesting", process_dfs_testing},
#endif
{"cfpcode", process_cfp_code},
{"antcfg", process_set_get_tx_rx_ant},
{"dscpmap", process_dscpmap},
{"changraph", process_chan_graph},
{"associate", process_associate_ssid_bssid},
{"httxbfcfg", process_tx_bf_cfg},
{"wpssession", process_wps_cfg},
{"port_ctrl", process_port_ctrl},
{"pb_bypass", process_bypassed_packet},
/* #ifdef FW_WAKEUP_METHOD */
{"fwwakeupmethod", process_fw_wakeup_method},
/* #endif */
{"sysclock", process_sysclock},
{"mc_cfg", process_multi_chan_cfg},
{"mc_policy", process_multi_chan_policy},
{"mc_cfg_ext", process_drcs_time_slicing_cfg},
#ifdef RX_PACKET_COALESCE
{"rxpktcoal_cfg", process_rx_pkt_coalesce_cfg},
#endif
#if defined(WIFI_DIRECT_SUPPORT)
{"cfg_noa", process_cfg_noa_opp_ps},
{"cfg_opp_ps", process_cfg_noa_opp_ps},
#endif
#ifdef WIFI_DIRECT_SUPPORT
{"miracastcfg", process_miracastcfg},
#endif
{"coex_rx_winsize", process_coex_rx_winsize},
{"dfs_repeater", process_dfs_repeater},
{"txaggrctrl", process_txaggrctrl},
{"autotdls", process_auto_tdls},
{"pcieregrw", process_pcie_reg_rw},
{"pciebar0regrw", process_pcie_bar0_reg_rw},
{"get_sensor_temp", process_get_sensor_temp},
{"11k_enable", process_11k_cfg},
{"neighbor_report", process_11k_neighbor_report},
{"channel_switch", process_extend_channel_switch},
{"auto_arp", process_auto_arp},
{"txrxhistogram", process_txrxhistogram},
{"indrstcfg", process_ind_rst_cfg},
{"tsf", process_tsf},
{"dot11_txrx", process_dot11_txrx},
{"per_pkt_cfg", process_per_pkt_cfg},
{"dyn_bw", process_dyn_bw},
{"tx_ampdu_prot_mode", process_tx_ampdu_prot_mode},
{"ctrldeauth", process_ctrldeauth},
{"robustcoex", process_robustcoex},
{"acs", process_acs},
{"bootsleep", process_bootsleep},
};
static char *usage[] = {
"Usage: ",
" mlanutl -v (version)",
" mlanutl <ifname> <cmd> [...]",
" where",
" ifname : wireless network interface name, such as mlanX or uapX",
" cmd :",
" 11dcfg",
" 11dclrtbl",
" addbapara",
" addbareject",
" addts",
" aggrpriotbl",
" amsduaggrctrl",
" antcfg",
#ifdef STA_SUPPORT
" arpfilter",
#endif
#ifdef REASSOCIATION
" assocessid",
" assocessid_bssid",
#endif
" associate",
" authtype",
" autotdls",
" bandcfg",
" bcninterval",
#if defined(WIFI_DIRECT_SUPPORT)
#if defined(STA_SUPPORT) && defined(UAP_SUPPORT)
" bssrole",
#endif
#endif
" cfgdata",
" cfpcode",
" changraph",
" coex_rx_winsize",
" countrycode",
" customie",
" deauth",
" deepsleep",
" delba",
" delts",
#if defined(DFS_TESTING_SUPPORT)
" dfstesting",
#endif
" dfs_repeater",
#ifdef DEBUG_LEVEL1
" drvdbg",
#endif
" dscpmap",
" esuppmode",
#ifdef STA_SUPPORT
" extcapcfg",
" cancelscan",
#endif
" fwmacaddr",
/* #ifdef FW_WAKEUP_METHOD */
" fwwakeupmethod",
/* #endif */
" getdatarate",
" getlog",
#ifdef STA_SUPPORT
" getscantable",
#endif
" getsignal",
#ifdef UAP_SUPPORT
" getstalist",
#endif
" hostcmd",
" hscfg",
" hssetpara",
" mgmtfilter",
" htcapinfo",
" htstreamcfg",
" mimoswitch",
#ifdef STA_SUPPORT
" signalextcfg",
" getsignalext",
" getsignalextv2",
#endif
" httxbfcap",
" httxbfcfg",
" httxcfg",
" inactivityto",
" ipaddr",
" linkstats",
#ifdef STA_SUPPORT
" listeninterval",
#endif
" macctrl",
" mefcfg",
" memrdwr",
#ifdef WIFI_DIRECT_SUPPORT
" miracastcfg",
#endif
" mgmtframectrl",
" mgmtframetx",
" netmon",
#if defined(WIFI_DIRECT_SUPPORT)
#if CFG80211_VERSION_CODE >= WIFI_DIRECT_KERNEL_VERSION
" cfg_noa",
" cfg_opp_ps",
#endif
#endif
" offchannel",
" otpuserdata",
" passphrase",
" pb_bypass",
" pcieregrw",
#if defined(STA_SUPPORT)
" pmfcfg",
#endif
" port_ctrl",
" powercons",
" pscfg",
#ifdef STA_SUPPORT
" psmode",
#endif
" qconfig",
" qoscfg",
" qstatus",
#ifdef STA_WEXT
" radioctrl",
#endif
" rdeeprom",
#if defined(REASSOCIATION)
" reassoctrl",
#endif
" regioncode",
" cfpinfo",
" regrdwr",
" rejectaddbareq",
" scancfg",
#ifdef STA_SUPPORT
" setuserscan",
#endif
" sleepparams",
" sleeppd",
" sysclock",
" tcpackenh",
" tdls_idle_time",
" tdls_channel_switch",
" tdls_config",
" tdls_cs_params",
" tdls_debug",
" tdls_disable_cs",
" tdls_discovery",
" tdls_link_status",
" tdls_powermode",
" tdls_setinfo",
" tdls_setup",
" tdls_stop_channel_switch",
" tdls_teardown",
" thermal",
" ts_status",
" tsf",
" txaggrctrl",
" txbufcfg",
" txcontrol",
" txpowercfg",
" txratecfg",
" verext",
" version",
" vhtcfg",
" opermodecfg",
" wakeupreason",
" warmreset",
" wmmcfg",
" wmmparamcfg",
" wpssession",
" wwscfg",
" mc_cfg",
" mc_policy",
" mc_cfg_ext",
#ifdef RX_PACKET_COALESCE
" rxpktcoal_cfg",
#endif
" get_sensor_temp",
" 11k_enable",
" neighbor_report",
" channel_switch",
" indrstcfg",
" dfs_offload",
" tx_ampdu_prot_mode",
" cwmode",
" dyn_bw",
" txrxhistogram",
" per_pkt_cfg",
" dot11_txrx",
" ctrldeauth",
" robustcoex",
};
/** Socket */
t_s32 sockfd;
/** Device name */
char dev_name[IFNAMSIZ + 1];
#define HOSTCMD "hostcmd"
#define BSSID_FILTER 1
#define SSID_FILTER 2
/********************************************************
Global Variables
********************************************************/
int setuserscan_filter = 0;
int num_ssid_filter = 0;
/********************************************************
Local Functions
********************************************************/
/**
* @brief isdigit for String.
*
* @param x Char string
* @return MLAN_STATUS_FAILURE for non-digit.
* MLAN_STATUS_SUCCESS for digit
*/
static int
ISDIGIT(char *x)
{
unsigned int i;
for (i = 0; i < strlen(x); i++)
if (isdigit(x[i]) == 0)
return MLAN_STATUS_FAILURE;
return MLAN_STATUS_SUCCESS;
}
/**
* Check of decimal or hex string
* @param num string
*/
#define IS_HEX_OR_DIGIT(num) \
(strncasecmp("0x", (num), 2)?ISDIGIT((num)):ishexstring((num)))
/**
* @brief Convert char to hex integer
*
* @param chr Char to convert
* @return Hex integer or 0
*/
int
hexval(t_s32 chr)
{
if (chr >= '0' && chr <= '9')
return chr - '0';
if (chr >= 'A' && chr <= 'F')
return chr - 'A' + 10;
if (chr >= 'a' && chr <= 'f')
return chr - 'a' + 10;
return 0;
}
/**
* @brief Hump hex data
*
* @param prompt A pointer prompt buffer
* @param p A pointer to data buffer
* @param len The len of data buffer
* @param delim Delim char
* @return Hex integer
*/
t_void
hexdump(char *prompt, t_void *p, t_s32 len, char delim)
{
t_s32 i;
t_u8 *s = p;
if (prompt) {
printf("%s: len=%d\n", prompt, (int)len);
}
for (i = 0; i < len; i++) {
if (i != len - 1)
printf("%02x%c", *s++, delim);
else
printf("%02x\n", *s);
if ((i + 1) % 16 == 0)
printf("\n");
}
printf("\n");
}
/**
* @brief Convert char to hex integer
*
* @param chr Char
* @return Hex integer
*/
t_u8
hexc2bin(char chr)
{
if (chr >= '0' && chr <= '9')
chr -= '0';
else if (chr >= 'A' && chr <= 'F')
chr -= ('A' - 10);
else if (chr >= 'a' && chr <= 'f')
chr -= ('a' - 10);
return chr;
}
/**
* @brief Convert string to hex integer
*
* @param s A pointer string buffer
* @return Hex integer
*/
t_u32
a2hex(char *s)
{
t_u32 val = 0;
if (!strncasecmp("0x", s, 2)) {
s += 2;
}
while (*s && isxdigit(*s)) {
val = (val << 4) + hexc2bin(*s++);
}
return val;
}
/*
* @brief Convert String to integer
*
* @param value A pointer to string
* @return Integer
*/
t_u32
a2hex_or_atoi(char *value)
{
if (value[0] == '0' && (value[1] == 'X' || value[1] == 'x')) {
return a2hex(value + 2);
} else {
return (t_u32)atoi(value);
}
}
/**
* @brief Convert string to hex
*
* @param ptr A pointer to data buffer
* @param chr A pointer to return integer
* @return A pointer to next data field
*/
char *
convert2hex(char *ptr, t_u8 *chr)
{
t_u8 val;
for (val = 0; *ptr && isxdigit(*ptr); ptr++) {
val = (val * 16) + hexval(*ptr);
}
*chr = val;
return ptr;
}
/**
* @brief Check the Hex String
* @param s A pointer to the string
* @return MLAN_STATUS_SUCCESS --HexString, MLAN_STATUS_FAILURE --not HexString
*/
int
ishexstring(char *s)
{
int ret = MLAN_STATUS_FAILURE;
t_s32 tmp;
if (!strncasecmp("0x", s, 2)) {
s += 2;
}
while (*s) {
tmp = toupper(*s);
if (((tmp >= 'A') && (tmp <= 'F')) ||
((tmp >= '0') && (tmp <= '9'))) {
ret = MLAN_STATUS_SUCCESS;
} else {
ret = MLAN_STATUS_FAILURE;
break;
}
s++;
}
return ret;
}
/**
* @brief Convert String to Integer
* @param buf A pointer to the string
* @return Integer
*/
int
atoval(char *buf)
{
if (!strncasecmp(buf, "0x", 2))
return a2hex(buf + 2);
else if (!ishexstring(buf))
return a2hex(buf);
else
return atoi(buf);
}
/**
* @brief Display usage
*
* @return NA
*/
static t_void
display_usage(t_void)
{
t_u32 i;
for (i = 0; i < NELEMENTS(usage); i++)
fprintf(stderr, "%s\n", usage[i]);
}
/**
* @brief Find and execute command
*
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS for success, otherwise failure
*/
static int
process_command(int argc, char *argv[])
{
int i = 0, ret = MLAN_STATUS_NOTFOUND;
struct command_node *node = NULL;
for (i = 0; i < (int)NELEMENTS(command_list); i++) {
node = &command_list[i];
if (!strcasecmp(node->name, argv[2])) {
ret = node->handler(argc, argv);
break;
}
}
return ret;
}
/**
* @brief Converts a string to hex value
*
* @param str A pointer to the string
* @param raw A pointer to the raw data buffer
* @return Number of bytes read
**/
int
string2raw(char *str, unsigned char *raw)
{
int len = (strlen(str) + 1) / 2;
do {
if (!isxdigit(*str)) {
return -1;
}
*str = toupper(*str);
*raw = CHAR2INT(*str) << 4;
++str;
*str = toupper(*str);
if (*str == '\0')
break;
*raw |= CHAR2INT(*str);
++raw;
} while (*++str != '\0');
return len;
}
/**
* @brief Prepare command buffer
* @param buffer Command buffer to be filled
* @param cmd Command id
* @param num Number of arguments
* @param args Arguments list
* @return MLAN_STATUS_SUCCESS
*/
static int
prepare_buffer(t_u8 *buffer, char *cmd, t_u32 num, char *args[])
{
t_u8 *pos = NULL;
unsigned int i = 0;
memset(buffer, 0, BUFFER_LENGTH);
/* Flag it for our use */
pos = buffer;
strncpy((char *)pos, CMD_MARVELL, strlen(CMD_MARVELL));
pos += (strlen(CMD_MARVELL));
/* Insert command */
strncpy((char *)pos, (char *)cmd, strlen(cmd));
pos += (strlen(cmd));
/* Insert arguments */
for (i = 0; i < num; i++) {
strncpy((char *)pos, args[i], strlen(args[i]));
pos += strlen(args[i]);
if (i < (num - 1)) {
strncpy((char *)pos, " ", strlen(" "));
pos += 1;
}
}
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Determine the netlink number
*
* @param i socket number
*
* @return Netlink number to use
*/
static int
get_netlink_num(int i)
{
FILE *fp;
int netlink_num = NETLINK_MARVELL;
char str[64];
char *srch = "netlink_num";
char filename[64];
if (i == 0) {
strcpy(filename, "/proc/mwlan/config");
} else if (i > 0) {
sprintf(filename, "/proc/mwlan/config%d", i);
}
/* Try to open /proc/mwlan/config$ */
fp = fopen(filename, "r");
if (fp) {
while (!feof(fp)) {
fgets(str, sizeof(str), fp);
if (strncmp(str, srch, strlen(srch)) == 0) {
netlink_num = atoi(str + strlen(srch) + 1);
break;
}
}
fclose(fp);
} else {
return -1;
}
return netlink_num;
}
/**
* @brief Read event data from netlink socket
*
* @param sk_fd Netlink socket handler
* @param buffer Pointer to the data buffer
* @param nlh Pointer to netlink message header
* @param msg Pointer to message header
*
* @return Number of bytes read or MLAN_EVENT_FAILURE
*/
int
read_event_netlink_socket(int sk_fd, unsigned char *buffer,
struct nlmsghdr *nlh, struct msghdr *msg)
{
int count = -1;
count = recvmsg(sk_fd, msg, 0);
#if DEBUG
printf("DBG:Waiting for message from NETLINK.\n");
#endif
if (count < 0) {
printf("ERR:NETLINK read failed!\n");
terminate_flag++;
return MLAN_EVENT_FAILURE;
}
#if DEBUG
printf("DBG:Received message payload (%d)\n", count);
#endif
if (count > NLMSG_SPACE(NL_MAX_PAYLOAD)) {
printf("ERR:Buffer overflow!\n");
return MLAN_EVENT_FAILURE;
}
memset(buffer, 0, NL_MAX_PAYLOAD);
memcpy(buffer, NLMSG_DATA(nlh), count - NLMSG_HDRLEN);
#if DEBUG
hexdump(buffer, count - NLMSG_HDRLEN, ' ');
#endif
return count - NLMSG_HDRLEN;
}
/**
* @brief Configure and read event data from netlink socket
*
* @param sk_fd Array of netlink sockets
* @param no_of_sk Number of netlink sockets opened
* @param recv_buf Pointer to the array of evt_buf structures
* @param timeout Socket listen timeout value
* @param nlh Pointer to netlink message header
* @param msg Pointer to message header
*
* @return Number of bytes read or MLAN_EVENT_FAILURE
*/
int
read_event(int *sk_fd, int no_of_sk, evt_buf *recv_buf, int timeout,
struct nlmsghdr *nlh, struct msghdr *msg)
{
struct timeval tv;
fd_set rfds;
int i = 0, max_sk_fd = sk_fd[0];
int ret = MLAN_EVENT_FAILURE;
/* Setup read fds */
FD_ZERO(&rfds);
for (i = 0; i < no_of_sk; i++) {
if (sk_fd[i] > max_sk_fd)
max_sk_fd = sk_fd[i];
if (sk_fd[i] > 0)
FD_SET(sk_fd[i], &rfds);
}
/* Initialize timeout value */
if (timeout != 0)
tv.tv_sec = timeout;
else
tv.tv_sec = UAP_RECV_WAIT_DEFAULT;
tv.tv_usec = 0;
/* Wait for reply */
ret = select(max_sk_fd + 1, &rfds, NULL, NULL, &tv);
if (ret == -1) {
/* Error */
terminate_flag++;
return MLAN_EVENT_FAILURE;
} else if (!ret) {
/* Timeout. Try again */
return MLAN_EVENT_FAILURE;
}
for (i = 0; i < no_of_sk; i++) {
if (sk_fd[i] > 0) {
if (FD_ISSET(sk_fd[i], &rfds)) {
/* Success */
recv_buf[i].flag = 1;
recv_buf[i].length =
read_event_netlink_socket(sk_fd[i],
recv_buf[i].
buffer, nlh,
msg);
ret += recv_buf[i].length;
}
}
}
return ret;
}
/**
* @brief Signal handler
*
* @param sig Received signal number
*
* @return N/A
*/
void
sig_handler(int sig)
{
printf("Stopping application.\n");
terminate_flag = 1;
}
/**
* @brief Wait event specified by event ID, and return back the pointer.
*
* @param eventID Event ID
* @param pEvent Pointer to the Event buffer
* @param pEventLen Pointer to the Event Length
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
wait_event(t_u32 eventID, t_u8 **pEvent, int *pEventLen)
{
int nl_sk[MAX_NO_OF_DEVICES];
struct nlmsghdr *nlh = NULL;
struct sockaddr_nl src_addr, dest_addr;
struct msghdr msg;
struct iovec iov;
evt_buf evt_recv_buf[MAX_NO_OF_DEVICES];
int num_events = 0;
event_header *event = NULL;
int ret = MLAN_EVENT_FAILURE;
int netlink_num[MAX_NO_OF_DEVICES];
char if_name[IFNAMSIZ + 1];
t_u32 event_id = 0;
int i = 0, no_of_sk = 0;
/* Currently, we support maximum 4 devices */
/* TODO: determine no_of_sk at run time */
no_of_sk = MAX_NO_OF_DEVICES;
for (i = 0; i < no_of_sk; i++) {
/* Initialise */
nl_sk[i] = -1;
netlink_num[i] = get_netlink_num(i);
if (netlink_num[i] >= 0) {
/* Open netlink socket */
nl_sk[i] = socket(PF_NETLINK, SOCK_RAW, netlink_num[i]);
if (nl_sk[i] < 0) {
printf("ERR:Could not open netlink socket.\n");
ret = MLAN_EVENT_FAILURE;
goto done;
}
/* Set source address */
memset(&src_addr, 0, sizeof(src_addr));
src_addr.nl_family = AF_NETLINK;
src_addr.nl_pid = getpid(); /* Our PID */
src_addr.nl_groups = NL_MULTICAST_GROUP;
/* Bind socket with source address */
if (bind
(nl_sk[i], (struct sockaddr *)&src_addr,
sizeof(src_addr)) < 0) {
printf("ERR:Could not bind socket!\n");
ret = MLAN_EVENT_FAILURE;
goto done;
}
/* Set destination address */
memset(&dest_addr, 0, sizeof(dest_addr));
dest_addr.nl_family = AF_NETLINK;
dest_addr.nl_pid = 0; /* Kernel */
dest_addr.nl_groups = NL_MULTICAST_GROUP;
/* Initialize netlink header */
nlh = (struct nlmsghdr *)
malloc(NLMSG_SPACE(NL_MAX_PAYLOAD));
if (!nlh) {
printf("ERR: Could not alloc buffer\n");
ret = MLAN_EVENT_FAILURE;
goto done;
}
memset(nlh, 0, NLMSG_SPACE(NL_MAX_PAYLOAD));
/* Initialize I/O vector */
iov.iov_base = (void *)nlh;
iov.iov_len = NLMSG_SPACE(NL_MAX_PAYLOAD);
/* Initialize message header */
memset(&msg, 0, sizeof(struct msghdr));
msg.msg_name = (void *)&dest_addr;
msg.msg_namelen = sizeof(dest_addr);
msg.msg_iov = &iov;
msg.msg_iovlen = 1;
memset(&evt_recv_buf[i], 0, sizeof(evt_buf));
}
}
signal(SIGTERM, sig_handler);
signal(SIGINT, sig_handler);
signal(SIGALRM, sig_handler);
while (1) {
if (terminate_flag) {
printf("Stopping!\n");
break;
}
ret = read_event(nl_sk, no_of_sk, evt_recv_buf, 0, nlh, &msg);
/* No result. Loop again */
if (ret == MLAN_EVENT_FAILURE) {
continue;
}
if (ret == 0) {
/* Zero bytes received */
printf("ERR:Received zero bytes!\n");
continue;
}
for (i = 0; i < no_of_sk; i++) {
if (evt_recv_buf[i].flag == 1) {
num_events++;
memcpy(&event_id, evt_recv_buf[i].buffer,
sizeof(event_id));
if (((event_id & 0xFF000000) == 0x80000000) ||
((event_id & 0xFF000000) == 0)) {
event = (event_header
*)(evt_recv_buf[i].buffer);
} else {
memset(if_name, 0, IFNAMSIZ + 1);
memcpy(if_name, evt_recv_buf[i].buffer,
IFNAMSIZ);
event = (event_header
*)((t_u8 *)(evt_recv_buf[i].
buffer) +
IFNAMSIZ);
ret -= IFNAMSIZ;
evt_recv_buf[i].length -= IFNAMSIZ;
}
if (event->event_id == eventID) {
*pEvent = (t_u8 *)event;
*pEventLen = evt_recv_buf[i].length;
goto done;
}
/* Reset event flag after reading */
evt_recv_buf[i].flag = 0;
}
}
fflush(stdout);
}
done:
for (i = 0; i < no_of_sk; i++) {
if (nl_sk[i] > 0)
close(nl_sk[i]);
}
if (nlh)
free(nlh);
return 0;
}
/**
* @brief Set Robustcoex gpiocfg
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_robustcoex(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd;
struct ifreq ifr;
if (argc <= 4) {
printf("Err: Invalid number of arguments\n");
printf("Usage: ./mlanutl <interface> robustcoex [gpiocfg] [value]\n");
return MLAN_STATUS_FAILURE;
}
if (strcmp(argv[3], "gpiocfg") == 0) {
if (argc != 7 && argc != 5) {
printf("ERR: Invalid number of arguments\n");
printf("Usage: ./mlanutl <interface> robustcoex gpiocfg [Enable][Gpionum][Gpiopolarity]\n");
printf("Usage: ./mlanutl <interface> robustcoex gpiocfg [Disable]\n");
return MLAN_STATUS_FAILURE;
}
} else {
printf("ERR: Invalid arguments\n");
printf("Usage: ./mlanutl <interface> robustcoex [gpiocfg][value]\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: robustcoex fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Do acs scan
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_acs(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd;
struct ifreq ifr;
acs_result *pacs_result = NULL;
int i = 0;
if (argc < 3) {
printf("Err: Invalid number of arguments\n");
printf("Usage: ./mlanutl <interface> acs [channels]\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: acs fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
if (cmd->used_len) {
pacs_result = (acs_result *) buffer;
printf("Best Channel: %d\n", pacs_result->best_ch);
if (pacs_result->ch_stats_num) {
printf("Channel Statistics:\n");
for (i = 0; i < pacs_result->ch_stats_num; i++)
printf("\t[CH %d]\t\ttotal_networks=%d\tcca_busy_duration=%d\n", pacs_result->ch_stats[i].chan_num, pacs_result->ch_stats[i].total_networks, pacs_result->ch_stats[i].cca_busy_duration);
}
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Get one line from the File
*
* @param fp File handler
* @param str Storage location for data.
* @param size Maximum number of characters to read.
* @param lineno A pointer to return current line number
* @return returns string or NULL
*/
char *
mlan_config_get_line(FILE * fp, char *str, t_s32 size, int *lineno)
{
char *start, *end;
int out, next_line;
if (!fp || !str)
return NULL;
do {
read_line:
if (!fgets(str, size, fp))
break;
start = str;
start[size - 1] = '\0';
end = start + strlen(str);
(*lineno)++;
out = 1;
while (out && (start < end)) {
next_line = 0;
/* Remove empty lines and lines starting with # */
switch (start[0]) {
case ' ': /* White space */
case '\t': /* Tab */
start++;
break;
case '#':
case '\n':
case '\0':
next_line = 1;
break;
case '\r':
if (start[1] == '\n')
next_line = 1;
else
start++;
break;
default:
out = 0;
break;
}
if (next_line)
goto read_line;
}
/* Remove # comments unless they are within a double quoted
* string. Remove trailing white space. */
end = strstr(start, "\"");
if (end) {
end = strstr(end + 1, "\"");
if (!end)
end = start;
} else
end = start;
end = strstr(end + 1, "#");
if (end)
*end-- = '\0';
else
end = start + strlen(start) - 1;
out = 1;
while (out && (start < end)) {
switch (*end) {
case ' ': /* White space */
case '\t': /* Tab */
case '\n':
case '\r':
*end = '\0';
end--;
break;
default:
out = 0;
break;
}
}
if (start == '\0')
continue;
return start;
} while (1);
return NULL;
}
/**
* @brief Parse function for a configuration line
*
* @param s Storage buffer for data
* @param size Maximum size of data
* @param stream File stream pointer
* @param line Pointer to current line within the file
* @param _pos Output string or NULL
* @return String or NULL
*/
static char *
config_get_line(char *s, int size, FILE * stream, int *line, char **_pos)
{
*_pos = mlan_config_get_line(stream, s, size, line);
return *_pos;
}
/**
* @brief Converts colon separated MAC address to hex value
*
* @param mac A pointer to the colon separated MAC string
* @param raw A pointer to the hex data buffer
* @return MLAN_STATUS_SUCCESS or MLAN_STATUS_FAILURE
* MAC_BROADCAST - if broadcast mac
* MAC_MULTICAST - if multicast mac
*/
static int
mac2raw(char *mac, t_u8 *raw)
{
unsigned int temp_raw[ETH_ALEN];
int num_tokens = 0;
int i;
if (strlen(mac) != ((2 * ETH_ALEN) + (ETH_ALEN - 1))) {
return MLAN_STATUS_FAILURE;
}
num_tokens = sscanf(mac, "%2x:%2x:%2x:%2x:%2x:%2x",
temp_raw + 0, temp_raw + 1, temp_raw + 2,
temp_raw + 3, temp_raw + 4, temp_raw + 5);
if (num_tokens != ETH_ALEN) {
return MLAN_STATUS_FAILURE;
}
for (i = 0; i < num_tokens; i++)
raw[i] = (t_u8)temp_raw[i];
if (memcmp(raw, "\xff\xff\xff\xff\xff\xff", ETH_ALEN) == 0) {
return MAC_BROADCAST;
} else if (raw[0] & 0x01) {
return MAC_MULTICAST;
}
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Parses a command line
*
* @param line The line to parse
* @param args Pointer to the argument buffer to be filled in
* @return Number of arguments in the line or EOF
*/
static int
parse_line(char *line, char *args[])
{
int arg_num = 0;
int is_start = 0;
int is_quote = 0;
int length = 0;
int i = 0;
arg_num = 0;
length = strlen(line);
/* Process line */
/* Find number of arguments */
is_start = 0;
is_quote = 0;
for (i = 0; i < length; i++) {
/* Ignore leading spaces */
if (is_start == 0) {
if (line[i] == ' ') {
continue;
} else if (line[i] == '\t') {
continue;
} else if (line[i] == '\n') {
break;
} else {
is_start = 1;
args[arg_num] = &line[i];
arg_num++;
}
}
if (is_start == 1) {
/* Ignore comments */
if (line[i] == '#') {
if (is_quote == 0) {
line[i] = '\0';
arg_num--;
}
break;
}
/* Separate by '=' */
if (line[i] == '=') {
line[i] = '\0';
is_start = 0;
continue;
}
/* Separate by ',' */
if (line[i] == ',') {
line[i] = '\0';
is_start = 0;
continue;
}
/* Change ',' to ' ', but not inside quotes */
if ((line[i] == ',') && (is_quote == 0)) {
line[i] = ' ';
continue;
}
}
/* Remove newlines */
if (line[i] == '\n') {
line[i] = '\0';
}
/* Check for quotes */
if (line[i] == '"') {
is_quote = (is_quote == 1) ? 0 : 1;
continue;
}
if (((line[i] == ' ') || (line[i] == '\t')) && (is_quote == 0)) {
line[i] = '\0';
is_start = 0;
continue;
}
}
return arg_num;
}
/**
* @brief Process version
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_version(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], 0, NULL);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: version fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
printf("Version string received: %s\n", buffer);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process band configuration
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_bandcfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
int i;
struct eth_priv_cmd *cmd = NULL;
struct eth_priv_bandcfg *bandcfg = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: bandcfg fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
bandcfg = (struct eth_priv_bandcfg *)buffer;
if (argc == 3) {
/* GET operation */
printf("Band Configuration:\n");
printf(" Infra Band: %d (", (int)bandcfg->config_bands);
for (i = 0; i < 7; i++) {
if ((bandcfg->config_bands >> i) & 0x1)
printf(" %s", band[i]);
}
printf(" )\n");
printf(" Adhoc Start Band: %d (",
(int)bandcfg->adhoc_start_band);
for (i = 0; i < 7; i++) {
if ((bandcfg->adhoc_start_band >> i) & 0x1)
printf(" %s", band[i]);
}
printf(" )\n");
printf(" Adhoc Start Channel: %d\n",
(int)bandcfg->adhoc_channel);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief get hostcmd data
*
* @param ln A pointer to line number
* @param buf A pointer to hostcmd data
* @param size A pointer to the return size of hostcmd buffer
* @return MLAN_STATUS_SUCCESS
*/
static int
mlan_get_hostcmd_data(FILE * fp, int *ln, t_u8 *buf, t_u16 *size)
{
t_s32 errors = 0, i;
char line[512], *pos, *pos1, *pos2, *pos3;
t_u16 len;
while ((pos = mlan_config_get_line(fp, line, sizeof(line), ln))) {
(*ln)++;
if (strcmp(pos, "}") == 0) {
break;
}
pos1 = strchr(pos, ':');
if (pos1 == NULL) {
printf("Line %d: Invalid hostcmd line '%s'\n", *ln,
pos);
errors++;
continue;
}
*pos1++ = '\0';
pos2 = strchr(pos1, '=');
if (pos2 == NULL) {
printf("Line %d: Invalid hostcmd line '%s'\n", *ln,
pos);
errors++;
continue;
}
*pos2++ = '\0';
len = a2hex_or_atoi(pos1);
if (len < 1 || len > BUFFER_LENGTH) {
printf("Line %d: Invalid hostcmd line '%s'\n", *ln,
pos);
errors++;
continue;
}
*size += len;
if (*pos2 == '"') {
pos2++;
pos3 = strchr(pos2, '"');
if (pos3 == NULL) {
printf("Line %d: invalid quotation '%s'\n", *ln,
pos);
errors++;
continue;
}
*pos3 = '\0';
memset(buf, 0, len);
memmove(buf, pos2, MIN(strlen(pos2), len));
buf += len;
} else if (*pos2 == '\'') {
pos2++;
pos3 = strchr(pos2, '\'');
if (pos3 == NULL) {
printf("Line %d: invalid quotation '%s'\n", *ln,
pos);
errors++;
continue;
}
*pos3 = ',';
for (i = 0; i < len; i++) {
pos3 = strchr(pos2, ',');
if (pos3 != NULL) {
*pos3 = '\0';
*buf++ = (t_u8)a2hex_or_atoi(pos2);
pos2 = pos3 + 1;
} else
*buf++ = 0;
}
} else if (*pos2 == '{') {
t_u16 tlvlen = 0, tmp_tlvlen;
mlan_get_hostcmd_data(fp, ln, buf + len, &tlvlen);
tmp_tlvlen = tlvlen;
while (len--) {
*buf++ = (t_u8)(tmp_tlvlen & 0xff);
tmp_tlvlen >>= 8;
}
*size += tlvlen;
buf += tlvlen;
} else {
t_u32 value = a2hex_or_atoi(pos2);
while (len--) {
*buf++ = (t_u8)(value & 0xff);
value >>= 8;
}
}
}
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Prepare host-command buffer
* @param fp File handler
* @param cmd_name Command name
* @param buf A pointer to comand buffer
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
int
prepare_host_cmd_buffer(FILE * fp, char *cmd_name, t_u8 *buf)
{
char line[256], cmdname[256], *pos, cmdcode[10];
HostCmd_DS_GEN *hostcmd;
t_u32 hostcmd_size = 0;
int ln = 0;
int cmdname_found = 0, cmdcode_found = 0;
hostcmd = (HostCmd_DS_GEN *)(buf + sizeof(t_u32));
hostcmd->command = 0xffff;
snprintf(cmdname, sizeof(cmdname), "%s={", cmd_name);
cmdname_found = 0;
while ((pos = mlan_config_get_line(fp, line, sizeof(line), &ln))) {
if (strcmp(pos, cmdname) == 0) {
cmdname_found = 1;
snprintf(cmdcode, sizeof(cmdcode), "CmdCode=");
cmdcode_found = 0;
while ((pos =
mlan_config_get_line(fp, line, sizeof(line),
&ln))) {
if (strncmp(pos, cmdcode, strlen(cmdcode)) == 0) {
cmdcode_found = 1;
hostcmd->command =
a2hex_or_atoi(pos +
strlen(cmdcode));
hostcmd->size = S_DS_GEN;
mlan_get_hostcmd_data(fp, &ln,
buf +
sizeof(t_u32) +
hostcmd->size,
&hostcmd->size);
break;
}
}
if (!cmdcode_found) {
fprintf(stderr,
"mlanutl: CmdCode not found in conf file\n");
return MLAN_STATUS_FAILURE;
}
break;
}
}
if (!cmdname_found) {
fprintf(stderr,
"mlanutl: cmdname '%s' is not found in conf file\n",
cmd_name);
return MLAN_STATUS_FAILURE;
}
hostcmd->seq_num = 0;
hostcmd->result = 0;
hostcmd->command = cpu_to_le16(hostcmd->command);
hostcmd->size = cpu_to_le16(hostcmd->size);
hostcmd_size = (t_u32)(hostcmd->size);
memcpy(buf, (t_u8 *)&hostcmd_size, sizeof(t_u32));
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Prints a MAC address in colon separated form from raw data
*
* @param raw A pointer to the hex data buffer
* @return N/A
*/
void
print_mac(t_u8 *raw)
{
printf("%02x:%02x:%02x:%02x:%02x:%02x", (unsigned int)raw[0],
(unsigned int)raw[1], (unsigned int)raw[2], (unsigned int)raw[3],
(unsigned int)raw[4], (unsigned int)raw[5]);
return;
}
/**
* @brief Process host_cmd response
* @param cmd_name Command name
* @param buf A pointer to the response buffer
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
int
process_host_cmd_resp(char *cmd_name, t_u8 *buf)
{
t_u32 hostcmd_size = 0;
HostCmd_DS_GEN *hostcmd = NULL;
int ret = MLAN_STATUS_SUCCESS;
buf += strlen(CMD_MARVELL) + strlen(cmd_name);
memcpy((t_u8 *)&hostcmd_size, buf, sizeof(t_u32));
buf += sizeof(t_u32);
hostcmd = (HostCmd_DS_GEN *)buf;
hostcmd->command = le16_to_cpu(hostcmd->command);
hostcmd->size = le16_to_cpu(hostcmd->size);
hostcmd->seq_num = le16_to_cpu(hostcmd->seq_num);
hostcmd->result = le16_to_cpu(hostcmd->result);
hostcmd->command &= ~HostCmd_RET_BIT;
if (!hostcmd->result) {
switch (hostcmd->command) {
case HostCmd_CMD_CFG_DATA:
{
HostCmd_DS_802_11_CFG_DATA *pstcfgData =
(HostCmd_DS_802_11_CFG_DATA *)(buf +
S_DS_GEN);
pstcfgData->data_len =
le16_to_cpu(pstcfgData->data_len);
pstcfgData->action =
le16_to_cpu(pstcfgData->action);
if (pstcfgData->action == HostCmd_ACT_GEN_GET) {
hexdump("cfgdata", pstcfgData->data,
pstcfgData->data_len, ' ');
}
break;
}
case HostCmd_CMD_802_11_TPC_ADAPT_REQ:
{
mlan_ioctl_11h_tpc_resp *tpcIoctlResp =
(mlan_ioctl_11h_tpc_resp *)(buf +
S_DS_GEN);
if (tpcIoctlResp->status_code == 0) {
printf("tpcrequest: txPower(%d), linkMargin(%d), rssi(%d)\n", tpcIoctlResp->tx_power, tpcIoctlResp->link_margin, tpcIoctlResp->rssi);
} else {
printf("tpcrequest: failure, status = %d\n", tpcIoctlResp->status_code);
}
break;
}
case HostCmd_CMD_802_11_CRYPTO:
{
t_u16 alg =
le16_to_cpu((t_u16)
*(buf + S_DS_GEN +
sizeof(t_u16)));
if (alg == CIPHER_TEST_AES_CCM ||
alg == CIPHER_TEST_GCMP) {
HostCmd_DS_802_11_CRYPTO_AES_CCM
*cmd_aes_ccm =
(HostCmd_DS_802_11_CRYPTO_AES_CCM
*)(buf + S_DS_GEN);
cmd_aes_ccm->encdec
=
le16_to_cpu(cmd_aes_ccm->
encdec);
cmd_aes_ccm->algorithm =
le16_to_cpu(cmd_aes_ccm->
algorithm);
cmd_aes_ccm->key_length =
le16_to_cpu(cmd_aes_ccm->
key_length);
cmd_aes_ccm->nonce_length =
le16_to_cpu(cmd_aes_ccm->
nonce_length);
cmd_aes_ccm->AAD_length =
le16_to_cpu(cmd_aes_ccm->
AAD_length);
cmd_aes_ccm->data.header.type =
le16_to_cpu(cmd_aes_ccm->data.
header.type);
cmd_aes_ccm->data.header.len =
le16_to_cpu(cmd_aes_ccm->data.
header.len);
printf("crypto_result: encdec=%d algorithm=%d, KeyLen=%d," " NonceLen=%d,AADLen=%d,dataLen=%d\n", cmd_aes_ccm->encdec, cmd_aes_ccm->algorithm, cmd_aes_ccm->key_length, cmd_aes_ccm->nonce_length, cmd_aes_ccm->AAD_length, cmd_aes_ccm->data.header.len);
hexdump("Key", cmd_aes_ccm->key,
cmd_aes_ccm->key_length, ' ');
hexdump("Nonce", cmd_aes_ccm->nonce,
cmd_aes_ccm->nonce_length, ' ');
hexdump("AAD", cmd_aes_ccm->AAD,
cmd_aes_ccm->AAD_length, ' ');
hexdump("Data", cmd_aes_ccm->data.data,
cmd_aes_ccm->data.header.len,
' ');
} else if (alg == CIPHER_TEST_WAPI) {
HostCmd_DS_802_11_CRYPTO_WAPI *cmd_wapi
=
(HostCmd_DS_802_11_CRYPTO_WAPI
*) (buf + S_DS_GEN);
cmd_wapi->encdec
= le16_to_cpu(cmd_wapi->encdec);
cmd_wapi->algorithm
=
le16_to_cpu(cmd_wapi->
algorithm);
cmd_wapi->key_length =
le16_to_cpu(cmd_wapi->
key_length);
cmd_wapi->nonce_length =
le16_to_cpu(cmd_wapi->
nonce_length);
cmd_wapi->AAD_length =
le16_to_cpu(cmd_wapi->
AAD_length);
printf("crypto_result: encdec=%d algorithm=%d, KeyLen=%d," " NonceLen=%d,AADLen=%d,dataLen=%d\n", cmd_wapi->encdec, cmd_wapi->algorithm, cmd_wapi->key_length, cmd_wapi->nonce_length, cmd_wapi->AAD_length, cmd_wapi->data_length);
hexdump("Key", cmd_wapi->key,
cmd_wapi->key_length, ' ');
hexdump("Nonce", cmd_wapi->nonce,
cmd_wapi->nonce_length, ' ');
hexdump("AAD", cmd_wapi->AAD,
cmd_wapi->AAD_length, ' ');
} else {
HostCmd_DS_802_11_CRYPTO *cmd =
(HostCmd_DS_802_11_CRYPTO *)(buf
+
S_DS_GEN);
cmd->encdec = le16_to_cpu(cmd->encdec);
cmd->algorithm =
le16_to_cpu(cmd->algorithm);
cmd->key_IV_length =
le16_to_cpu(cmd->key_IV_length);
cmd->key_length =
le16_to_cpu(cmd->key_length);
cmd->data.header.type =
le16_to_cpu(cmd->data.header.
type);
cmd->data.header.len =
le16_to_cpu(cmd->data.header.
len);
printf("crypto_result: encdec=%d algorithm=%d,KeyIVLen=%d," " KeyLen=%d,dataLen=%d\n", cmd->encdec, cmd->algorithm, cmd->key_IV_length, cmd->key_length, cmd->data.header.len);
hexdump("KeyIV", cmd->keyIV,
cmd->key_IV_length, ' ');
hexdump("Key", cmd->key,
cmd->key_length, ' ');
hexdump("Data", cmd->data.data,
cmd->data.header.len, ' ');
}
break;
}
case HostCmd_CMD_802_11_AUTO_TX:
{
HostCmd_DS_802_11_AUTO_TX *at =
(HostCmd_DS_802_11_AUTO_TX *)(buf +
S_DS_GEN);
if (le16_to_cpu(at->action) ==
HostCmd_ACT_GEN_GET) {
if (S_DS_GEN + sizeof(at->action) ==
hostcmd->size) {
printf("auto_tx not configured\n");
} else {
MrvlIEtypesHeader_t *header =
&at->auto_tx.header;
header->type =
le16_to_cpu(header->
type);
header->len =
le16_to_cpu(header->
len);
if ((S_DS_GEN +
sizeof(at->action)
+
sizeof(MrvlIEtypesHeader_t)
+ header->len ==
hostcmd->size) &&
(header->type ==
TLV_TYPE_AUTO_TX)) {
AutoTx_MacFrame_t *atmf
=
&at->auto_tx.
auto_tx_mac_frame;
printf("Interval: %d second(s)\n", le16_to_cpu(atmf->interval));
printf("Priority: %#x\n", atmf->priority);
printf("Frame Length: %d\n", le16_to_cpu(atmf->frame_len));
printf("Dest Mac Address: " "%02x:%02x:%02x:%02x:%02x:%02x\n", atmf->dest_mac_addr[0], atmf->dest_mac_addr[1], atmf->dest_mac_addr[2], atmf->dest_mac_addr[3], atmf->dest_mac_addr[4], atmf->dest_mac_addr[5]);
printf("Src Mac Address: " "%02x:%02x:%02x:%02x:%02x:%02x\n", atmf->src_mac_addr[0], atmf->src_mac_addr[1], atmf->src_mac_addr[2], atmf->src_mac_addr[3], atmf->src_mac_addr[4], atmf->src_mac_addr[5]);
hexdump("Frame Payload",
atmf->payload,
le16_to_cpu
(atmf->
frame_len)
-
MLAN_MAC_ADDR_LENGTH
* 2, ' ');
} else {
printf("incorrect auto_tx command response\n");
}
}
}
break;
}
case HostCmd_CMD_802_11_SUBSCRIBE_EVENT:
{
HostCmd_DS_802_11_SUBSCRIBE_EVENT *se =
(HostCmd_DS_802_11_SUBSCRIBE_EVENT
*)(buf + S_DS_GEN);
if (le16_to_cpu(se->action) ==
HostCmd_ACT_GEN_GET) {
int len =
S_DS_GEN +
sizeof
(HostCmd_DS_802_11_SUBSCRIBE_EVENT);
printf("\nEvent\t\tValue\tFreq\tsubscribed\n\n");
while (len < hostcmd->size) {
MrvlIEtypesHeader_t *header =
(MrvlIEtypesHeader_t
*)(buf + len);
switch (le16_to_cpu
(header->type)) {
case TLV_TYPE_RSSI_LOW:
{
MrvlIEtypes_RssiThreshold_t
*low_rssi
=
(MrvlIEtypes_RssiThreshold_t
*)(buf
+
len);
printf("Beacon Low RSSI\t%d\t%d\t%s\n", low_rssi->RSSI_value, low_rssi->RSSI_freq, (le16_to_cpu(se->events) & 0x0001) ? "yes" : "no");
break;
}
case TLV_TYPE_SNR_LOW:
{
MrvlIEtypes_SnrThreshold_t
*low_snr
=
(MrvlIEtypes_SnrThreshold_t
*)(buf
+
len);
printf("Beacon Low SNR\t%d\t%d\t%s\n", low_snr->SNR_value, low_snr->SNR_freq, (le16_to_cpu(se->events) & 0x0002) ? "yes" : "no");
break;
}
case TLV_TYPE_FAILCOUNT:
{
MrvlIEtypes_FailureCount_t
*failure_count
=
(MrvlIEtypes_FailureCount_t
*)(buf
+
len);
printf("Failure Count\t%d\t%d\t%s\n", failure_count->fail_value, failure_count->fail_freq, (le16_to_cpu(se->events) & 0x0004) ? "yes" : "no");
break;
}
case TLV_TYPE_BCNMISS:
{
MrvlIEtypes_BeaconsMissed_t
*bcn_missed
=
(MrvlIEtypes_BeaconsMissed_t
*)(buf
+
len);
printf("Beacon Missed\t%d\tN/A\t%s\n", bcn_missed->beacon_missed, (le16_to_cpu(se->events) & 0x0008) ? "yes" : "no");
break;
}
case TLV_TYPE_RSSI_HIGH:
{
MrvlIEtypes_RssiThreshold_t
*high_rssi
=
(MrvlIEtypes_RssiThreshold_t
*)(buf
+
len);
printf("Bcn High RSSI\t%d\t%d\t%s\n", high_rssi->RSSI_value, high_rssi->RSSI_freq, (le16_to_cpu(se->events) & 0x0010) ? "yes" : "no");
break;
}
case TLV_TYPE_SNR_HIGH:
{
MrvlIEtypes_SnrThreshold_t
*high_snr
=
(MrvlIEtypes_SnrThreshold_t
*)(buf
+
len);
printf("Beacon High SNR\t%d\t%d\t%s\n", high_snr->SNR_value, high_snr->SNR_freq, (le16_to_cpu(se->events) & 0x0020) ? "yes" : "no");
break;
}
case TLV_TYPE_RSSI_LOW_DATA:
{
MrvlIEtypes_RssiThreshold_t
*low_rssi
=
(MrvlIEtypes_RssiThreshold_t
*)(buf
+
len);
printf("Data Low RSSI\t%d\t%d\t%s\n", low_rssi->RSSI_value, low_rssi->RSSI_freq, (le16_to_cpu(se->events) & 0x0040) ? "yes" : "no");
break;
}
case TLV_TYPE_SNR_LOW_DATA:
{
MrvlIEtypes_SnrThreshold_t
*low_snr
=
(MrvlIEtypes_SnrThreshold_t
*)(buf
+
len);
printf("Data Low SNR\t%d\t%d\t%s\n", low_snr->SNR_value, low_snr->SNR_freq, (le16_to_cpu(se->events) & 0x0080) ? "yes" : "no");
break;
}
case TLV_TYPE_RSSI_HIGH_DATA:
{
MrvlIEtypes_RssiThreshold_t
*high_rssi
=
(MrvlIEtypes_RssiThreshold_t
*)(buf
+
len);
printf("Data High RSSI\t%d\t%d\t%s\n", high_rssi->RSSI_value, high_rssi->RSSI_freq, (le16_to_cpu(se->events) & 0x0100) ? "yes" : "no");
break;
}
case TLV_TYPE_SNR_HIGH_DATA:
{
MrvlIEtypes_SnrThreshold_t
*high_snr
=
(MrvlIEtypes_SnrThreshold_t
*)(buf
+
len);
printf("Data High SNR\t%d\t%d\t%s\n", high_snr->SNR_value, high_snr->SNR_freq, (le16_to_cpu(se->events) & 0x0200) ? "yes" : "no");
break;
}
case TLV_TYPE_LINK_QUALITY:
{
MrvlIEtypes_LinkQuality_t
*link_qual
=
(MrvlIEtypes_LinkQuality_t
*)(buf
+
len);
printf("Link Quality Parameters:\n");
printf("------------------------\n");
printf("Link Quality Event Subscribed\t%s\n", (le16_to_cpu(se->events) & 0x0400) ? "yes" : "no");
printf("Link SNR Threshold = %d\n", le16_to_cpu(link_qual->link_SNR_thrs));
printf("Link SNR Frequency = %d\n", le16_to_cpu(link_qual->link_SNR_freq));
printf("Min Rate Value = %d\n", le16_to_cpu(link_qual->min_rate_val));
printf("Min Rate Frequency = %d\n", le16_to_cpu(link_qual->min_rate_freq));
printf("Tx Latency Value = %d\n", le32_to_cpu(link_qual->tx_latency_val));
printf("Tx Latency Threshold = %d\n", le32_to_cpu(link_qual->tx_latency_thrs));
break;
}
case TLV_TYPE_PRE_BEACON_LOST:
{
MrvlIEtypes_PreBeaconLost_t
*pre_bcn_lost
=
(MrvlIEtypes_PreBeaconLost_t
*)(buf
+
len);
printf("------------------------\n");
printf("Pre-Beacon Lost Event Subscribed\t%s\n", (le16_to_cpu(se->events) & 0x0800) ? "yes" : "no");
printf("Pre-Beacon Lost: %d\n", pre_bcn_lost->pre_beacon_lost);
break;
}
default:
printf("Unknown subscribed event TLV Type=%#x," " Len=%d\n", le16_to_cpu(header->type), le16_to_cpu(header->len));
break;
}
len += (sizeof
(MrvlIEtypesHeader_t)
+
le16_to_cpu(header->
len));
}
}
break;
}
case HostCmd_CMD_MAC_REG_ACCESS:
case HostCmd_CMD_BBP_REG_ACCESS:
case HostCmd_CMD_RF_REG_ACCESS:
case HostCmd_CMD_CAU_REG_ACCESS:
{
HostCmd_DS_REG *preg =
(HostCmd_DS_REG *)(buf + S_DS_GEN);
preg->action = le16_to_cpu(preg->action);
if (preg->action == HostCmd_ACT_GEN_GET) {
preg->value = le32_to_cpu(preg->value);
printf("value = 0x%08x\n", preg->value);
}
break;
}
case HostCmd_CMD_MEM_ACCESS:
{
HostCmd_DS_MEM *pmem =
(HostCmd_DS_MEM *)(buf + S_DS_GEN);
pmem->action = le16_to_cpu(pmem->action);
if (pmem->action == HostCmd_ACT_GEN_GET) {
pmem->value = le32_to_cpu(pmem->value);
printf("value = 0x%08x\n", pmem->value);
}
break;
}
case HostCmd_CMD_LINK_STATS_SUMMARY:
{
HostCmd_DS_LINK_STATS_SUMMARY *linkstats =
(HostCmd_DS_LINK_STATS_SUMMARY *)(buf +
S_DS_GEN);
/* GET operation */
printf("Link Statistics: \n");
/* format */
printf("Duration: %u\n",
(int)le32_to_cpu(linkstats->
timeSinceLastQuery_ms));
printf("Beacon count: %u\n",
le16_to_cpu(linkstats->bcnCnt));
printf("Beacon missing: %u\n",
le16_to_cpu(linkstats->bcnMiss));
printf("Beacon RSSI avg: %d\n",
le16_to_cpu(linkstats->bcnRssiAvg));
printf("Beacon SNR avg: %d\n",
le16_to_cpu(linkstats->bcnSnrAvg));
printf("Rx packets: %u\n",
(int)le32_to_cpu(linkstats->rxPkts));
printf("Rx RSSI avg: %d\n",
le16_to_cpu(linkstats->rxRssiAvg));
printf("Rx SNR avg: %d\n",
le16_to_cpu(linkstats->rxSnrAvg));
printf("Tx packets: %u\n",
(int)le32_to_cpu(linkstats->txPkts));
printf("Tx Attempts: %u\n",
(int)le32_to_cpu(linkstats->txAttempts));
printf("Tx Failures: %u\n",
(int)le32_to_cpu(linkstats->txFailures));
printf("Tx Initial Rate: %s\n",
rateIdStr[linkstats->txInitRate]);
printf("Tx AC VO: %u [ %u ]\n",
le16_to_cpu(linkstats->
txQueuePktCnt[WMM_AC_VO]),
(int)le32_to_cpu(linkstats->
txQueueDelay[WMM_AC_VO])
/ 1000);
printf("Tx AC VI: %u [ %u ]\n",
le16_to_cpu(linkstats->
txQueuePktCnt[WMM_AC_VI]),
(int)le32_to_cpu(linkstats->
txQueueDelay[WMM_AC_VI])
/ 1000);
printf("Tx AC BE: %u [ %u ]\n",
le16_to_cpu(linkstats->
txQueuePktCnt[WMM_AC_BE]),
(int)le32_to_cpu(linkstats->
txQueueDelay[WMM_AC_BE])
/ 1000);
printf("Tx AC BK: %u [ %u ]\n",
le16_to_cpu(linkstats->
txQueuePktCnt[WMM_AC_BK]),
(int)le32_to_cpu(linkstats->
txQueueDelay[WMM_AC_BK])
/ 1000);
break;
}
case HostCmd_CMD_WMM_PARAM_CONFIG:
{
HostCmd_DS_WMM_PARAM_CONFIG *wmm_param =
(HostCmd_DS_WMM_PARAM_CONFIG *) (buf +
S_DS_GEN);
printf("WMM Params: \n");
printf("\tBE: AIFSN=%d, CW_MAX=%d CW_MIN=%d, TXOP=%d\n", wmm_param->ac_params[AC_BE].aci_aifsn.aifsn, wmm_param->ac_params[AC_BE].ecw.ecw_max, wmm_param->ac_params[AC_BE].ecw.ecw_min, le16_to_cpu(wmm_param->ac_params[AC_BE].tx_op_limit));
printf("\tBK: AIFSN=%d, CW_MAX=%d CW_MIN=%d, TXOP=%d\n", wmm_param->ac_params[AC_BK].aci_aifsn.aifsn, wmm_param->ac_params[AC_BK].ecw.ecw_max, wmm_param->ac_params[AC_BK].ecw.ecw_min, le16_to_cpu(wmm_param->ac_params[AC_BK].tx_op_limit));
printf("\tVI: AIFSN=%d, CW_MAX=%d CW_MIN=%d, TXOP=%d\n", wmm_param->ac_params[AC_VI].aci_aifsn.aifsn, wmm_param->ac_params[AC_VI].ecw.ecw_max, wmm_param->ac_params[AC_VI].ecw.ecw_min, le16_to_cpu(wmm_param->ac_params[AC_VI].tx_op_limit));
printf("\tVO: AIFSN=%d, CW_MAX=%d CW_MIN=%d, TXOP=%d\n", wmm_param->ac_params[AC_VO].aci_aifsn.aifsn, wmm_param->ac_params[AC_VO].ecw.ecw_max, wmm_param->ac_params[AC_VO].ecw.ecw_min, le16_to_cpu(wmm_param->ac_params[AC_VO].tx_op_limit));
break;
}
default:
printf("HOSTCMD_RESP: CmdCode=%#04x, Size=%#04x,"
" SeqNum=%#04x, Result=%#04x\n",
hostcmd->command, hostcmd->size,
hostcmd->seq_num, hostcmd->result);
hexdump("payload",
(t_void *)(buf + S_DS_GEN),
hostcmd->size - S_DS_GEN, ' ');
break;
}
} else {
printf("HOSTCMD failed: CmdCode=%#04x, Size=%#04x,"
" SeqNum=%#04x, Result=%#04x\n",
hostcmd->command, hostcmd->size,
hostcmd->seq_num, hostcmd->result);
}
return ret;
}
/**
* @brief Trims leading and traling spaces only
* @param str A pointer to argument string
* @return pointer to trimmed string
*/
char *
trim_spaces(char *str)
{
char *str_end = NULL;
if (!str)
return NULL;
/* Trim leading spaces */
while (!*str && isspace(*str))
str++;
if (*str == 0) /* All spaces? */
return str;
/* Trim trailing spaces */
str_end = str + strlen(str) - 1;
while (str_end > str && isspace(*str_end))
str_end--;
/* null terminate the string */
*(str_end + 1) = '\0';
return str;
}
/**
* @brief Process hostcmd command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_hostcmd(int argc, char *argv[])
{
t_u8 *buffer = NULL, *raw_buf = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
FILE *fp = NULL;
FILE *fp_raw = NULL;
FILE *fp_dtsi = NULL;
char cmdname[256];
boolean call_ioctl = TRUE;
t_u32 buf_len = 0, i, j, k;
char *line = NULL, *pos = NULL;
int li = 0, blk_count = 0, ob = 0;
int ret = MLAN_STATUS_SUCCESS;
struct cmd_node {
char cmd_string[256];
struct cmd_node *next;
};
struct cmd_node *command = NULL, *header = NULL, *new_node = NULL;
if (argc < 5) {
printf("Error: invalid no of arguments\n");
printf("Syntax: ./mlanutl mlanX hostcmd <hostcmd.conf> <cmdname>\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
snprintf(cmdname, sizeof(cmdname), "%s", argv[4]);
if (!strcmp(cmdname, "generate_raw")) {
call_ioctl = FALSE;
}
if (!call_ioctl && argc != 6) {
printf("Error: invalid no of arguments\n");
printf("Syntax: ./mlanutl mlanX hostcmd <hostcmd.conf> %s <raw_data_file>\n", cmdname);
ret = MLAN_STATUS_FAILURE;
goto done;
}
fp = fopen(argv[3], "r");
if (fp == NULL) {
fprintf(stderr, "Cannot open file %s\n", argv[3]);
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
if (call_ioctl) {
/* Prepare the hostcmd buffer */
prepare_buffer(buffer, argv[2], 0, NULL);
if (MLAN_STATUS_FAILURE ==
prepare_host_cmd_buffer(fp, cmdname,
buffer + strlen(CMD_MARVELL) +
strlen(argv[2]))) {
fclose(fp);
ret = MLAN_STATUS_FAILURE;
goto done;
}
fclose(fp);
} else {
line = (char *)malloc(MAX_CONFIG_LINE);
if (!line) {
printf("ERR:Cannot allocate memory for line\n");
fclose(fp);
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(line, 0, MAX_CONFIG_LINE);
while (config_get_line(line, MAX_CONFIG_LINE, fp, &li, &pos)) {
line = trim_spaces(line);
if (line[strlen(line) - 1] == '{') {
if (ob == 0) {
new_node =
(struct cmd_node *)
malloc(sizeof(struct cmd_node));
if (!new_node) {
printf("ERR:Cannot allocate memory for cmd_node\n");
fclose(fp);
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(new_node, 0,
sizeof(struct cmd_node));
new_node->next = NULL;
if (blk_count == 0) {
header = new_node;
command = new_node;
} else {
command->next = new_node;
command = new_node;
}
strncpy(command->cmd_string, line,
(strchr(line, '=') - line));
memmove(command->cmd_string,
trim_spaces(command->
cmd_string),
strlen(trim_spaces
(command->cmd_string)) +
1);
}
ob++;
continue; /* goto while() */
}
if (line[strlen(line) - 1] == '}') {
ob--;
if (ob == 0)
blk_count++;
continue; /* goto while() */
}
}
rewind(fp); /* Set the source file pointer to the beginning again */
command = header; /* Set 'command' at the beginning of the command list */
fp_raw = fopen(argv[5], "w");
if (fp_raw == NULL) {
fprintf(stderr,
"Cannot open the destination raw_data file %s\n",
argv[5]);
fclose(fp);
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* prepare .dtsi output */
snprintf(cmdname, sizeof(cmdname), "%s.dtsi", argv[5]);
fp_dtsi = fopen(cmdname, "w");
if (fp_dtsi == NULL) {
fprintf(stderr, "Cannot open the destination file %s\n",
cmdname);
fclose(fp);
fclose(fp_raw);
ret = MLAN_STATUS_FAILURE;
goto done;
}
for (k = 0; k < blk_count && command != NULL; k++) {
if (MLAN_STATUS_FAILURE ==
prepare_host_cmd_buffer(fp, command->cmd_string,
buffer))
memset(buffer, 0, BUFFER_LENGTH);
memcpy(&buf_len, buffer, sizeof(t_u32));
if (buf_len) {
raw_buf = buffer + sizeof(t_u32); /* raw_buf points to start of actual <raw data> */
printf("buf_len = %d\n", (int)buf_len);
if (k > 0)
fprintf(fp_raw, "\n\n");
fprintf(fp_raw, "%s={\n", command->cmd_string);
fprintf(fp_dtsi,
"/ {\n\tmarvell_cfgdata {\n\t\tmarvell,%s = /bits/ 8 <\n",
command->cmd_string);
i = j = 0;
while (i < buf_len) {
for (j = 0; j < 16; j++) {
fprintf(fp_raw, "%02x ",
*(raw_buf + i));
if (i >= 8) {
fprintf(fp_dtsi,
"0x%02x",
*(raw_buf + i));
if ((j < 16 - 1) &&
(i < buf_len - 1))
fprintf(fp_dtsi,
" ");
}
if (++i >= buf_len)
break;
}
fputc('\n', fp_raw);
fputc('\n', fp_dtsi);
}
fprintf(fp_raw, "}");
fprintf(fp_dtsi, "\t\t>;\n\t};\n};\n");
}
command = command->next;
rewind(fp);
}
fclose(fp_dtsi);
fclose(fp_raw);
fclose(fp);
}
if (call_ioctl) {
cmd = (struct eth_priv_cmd *)
malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: hostcmd fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
process_host_cmd_resp(argv[2], buffer);
}
done:
while (header) {
command = header;
header = header->next;
free(command);
}
if (line)
free(line);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Process HT Tx configuration
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_httxcfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
t_u32 *data = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: httxcfg fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (argc == 3) {
/* Get result */
data = (t_u32 *)buffer;
printf("HT Tx cfg: \n");
printf(" BG band: 0x%08x\n", data[0]);
printf(" A band: 0x%08x\n", data[1]);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process HT capability configuration
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_htcapinfo(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct eth_priv_htcapinfo *ht_cap = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: htcapinfo fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
if (argc == 3) {
ht_cap = (struct eth_priv_htcapinfo *)buffer;
printf("HT cap info: \n");
printf(" BG band: 0x%08x\n", ht_cap->ht_cap_info_bg);
printf(" A band: 0x%08x\n", ht_cap->ht_cap_info_a);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process HT Add BA parameters
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_addbapara(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
struct eth_priv_addba *addba = NULL;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: addbapara fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (argc == 3) {
/* Get */
addba = (struct eth_priv_addba *)buffer;
printf("Add BA configuration: \n");
printf(" Time out : %d\n", addba->time_out);
printf(" TX window: %d\n", addba->tx_win_size);
printf(" RX window: %d\n", addba->rx_win_size);
printf(" TX AMSDU : %d\n", addba->tx_amsdu);
printf(" RX AMSDU : %d\n", addba->rx_amsdu);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process Aggregation priority table parameters
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_aggrpriotbl(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
int i;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: aggrpriotbl fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (argc == 3) {
/* Get */
printf("Aggregation priority table cfg: \n");
printf(" TID AMPDU AMSDU \n");
for (i = 0; i < MAX_NUM_TID; i++) {
printf(" %d %3d %3d \n",
i, buffer[2 * i], buffer[2 * i + 1]);
}
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process HT Add BA reject configurations
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_addbareject(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
int i;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: addbareject fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (argc == 3) {
/* Get */
printf("Add BA reject configuration: \n");
printf(" TID Reject \n");
for (i = 0; i < MAX_NUM_TID; i++) {
printf(" %d %d\n", i, buffer[i]);
}
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process HT Del BA command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_delba(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: delba fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process reject addba req command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_rejectaddbareq(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: rejectaddbareq fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
printf("Reject addba req command response: %s\n", buffer);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process VHT configuration
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_vhtcfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct eth_priv_vhtcfg vhtcfg;
struct ifreq ifr;
t_u8 i, num = 0;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* Sanity tests */
if (argc < 5) {
printf("Insufficient parameters\n");
printf("For STA interface: mlanutl mlanX vhtcfg <band> <txrx> [bwcfg] [vhtcap]\n");
printf("For uAP interface: mlanutl uapX vhtcfg <band> <txrx> [bwcfg] [vhtcap] [vht_tx_mcs] [vht_rx_mcs]\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: vhtcfg fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
/* the first attribute is the number of vhtcfg entries */
num = *buffer;
if (argc == 5) {
/* GET operation */
printf("11AC VHT Configuration: \n");
for (i = 0; i < num; i++) {
memcpy(&vhtcfg, buffer + 1 + i * sizeof(vhtcfg),
sizeof(vhtcfg));
/* Band */
if (vhtcfg.band == 1)
printf("Band: 2.4G\n");
else
printf("Band: 5G\n");
/* BW confi9 */
if (vhtcfg.bwcfg == 0)
printf(" BW config: Follow BW in the 11N config\n");
else
printf(" BW config: Follow BW in VHT Capabilities\n");
/* Tx/Rx */
if (vhtcfg.txrx & 0x1)
printf(" VHT operation for Tx: 0x%08x\n",
vhtcfg.vht_cap_info);
if (vhtcfg.txrx & 0x2)
/* VHT capabilities */
printf(" VHT Capabilities Info: 0x%08x\n",
vhtcfg.vht_cap_info);
/* MCS */
if (vhtcfg.txrx & 0x2) {
printf(" Tx MCS set: 0x%04x\n",
vhtcfg.vht_tx_mcs);
printf(" Rx MCS set: 0x%04x\n",
vhtcfg.vht_rx_mcs);
}
}
} else {
/* SET operation */
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process Operating Mode Notification configuration
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_opermodecfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct eth_priv_opermodecfg *cfg = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: opermodecfg fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
cfg = (struct eth_priv_opermodecfg *)(buffer);
printf("11AC Operating Mode Notification Configuration: \n");
printf(" bw: %d\n", cfg->bw);
printf(" nss: %d\n", cfg->nss);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
static char *rate_format[3] = { "LG", "HT", "VHT" };
static char *lg_rate[] = { "1 Mbps", "2 Mbps", "5.5 Mbps", "11 Mbps",
"6 Mbps", "9 Mbps", "12 Mbps", "18 Mbps",
"24 Mbps", "36 Mbps", "48 Mbps", "54 Mbps"
};
/**
* @brief Process Get data rate
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_datarate(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct eth_priv_data_rate *datarate = NULL;
struct ifreq ifr;
char *bw[] = { "20 MHz", "40 MHz", "80 MHz", "160 MHz" };
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], 0, NULL);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: getdatarate fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
datarate = (struct eth_priv_data_rate *)buffer;
printf("Data Rate:\n");
printf(" TX: \n");
if (datarate->tx_rate_format <= 2) {
printf(" Type: %s\n", rate_format[datarate->tx_rate_format]);
if ((datarate->tx_rate_format == 0) &&
datarate->tx_data_rate <= 11)
/* LG */
printf(" Rate: %s\n",
lg_rate[datarate->tx_data_rate]);
else {
/* HT and VHT */
if (datarate->tx_bw <= 3)
printf(" BW: %s\n", bw[datarate->tx_bw]);
if (datarate->tx_gi == 0)
printf(" GI: Long\n");
else
printf(" GI: Short\n");
if (datarate->tx_rate_format == 3)
printf(" NSS: %d\n", datarate->tx_nss);
if (datarate->tx_mcs_index != 0xFF)
printf(" MCS: MCS %d\n",
(int)datarate->tx_mcs_index);
else
printf(" MCS: Auto\n");
printf(" Rate: %f Mbps\n",
(float)datarate->tx_data_rate / 2);
}
}
printf(" RX: \n");
if (datarate->rx_rate_format <= 2) {
printf(" Type: %s\n", rate_format[datarate->rx_rate_format]);
if ((datarate->rx_rate_format == 0) &&
datarate->rx_data_rate <= 11)
/* LG */
printf(" Rate: %s\n",
lg_rate[datarate->rx_data_rate]);
else {
/* HT and VHT */
if (datarate->rx_bw <= 3)
printf(" BW: %s\n", bw[datarate->rx_bw]);
if (datarate->rx_gi == 0)
printf(" GI: Long\n");
else
printf(" GI: Short\n");
if (datarate->rx_rate_format == 3)
printf(" NSS: %d\n", datarate->rx_nss);
if (datarate->rx_mcs_index != 0xFF)
printf(" MCS: MCS %d\n",
(int)datarate->rx_mcs_index);
else
printf(" MCS: Auto\n");
printf(" Rate: %f Mbps\n",
(float)datarate->rx_data_rate / 2);
}
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process tx rate configuration
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_txratecfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct eth_priv_tx_rate_cfg *txratecfg = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: txratecfg fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
txratecfg = (struct eth_priv_tx_rate_cfg *)buffer;
if (argc == 3) {
/* GET operation */
printf("Tx Rate Configuration: \n");
/* format */
if (txratecfg->rate_format == 0xFF) {
printf(" Type: 0xFF (Auto)\n");
} else if (txratecfg->rate_format <= 2) {
printf(" Type: %d (%s)\n",
txratecfg->rate_format,
rate_format[txratecfg->rate_format]);
if (txratecfg->rate_format == 0)
printf(" Rate Index: %d (%s)\n",
txratecfg->rate_index,
lg_rate[txratecfg->rate_index]);
else if (txratecfg->rate_format >= 1)
printf(" MCS Index: %d\n",
(int)txratecfg->rate_index);
if (txratecfg->rate_format == 2)
printf(" NSS: %d\n",
(int)txratecfg->nss);
} else {
printf(" Unknown rate format.\n");
}
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process get wireless stats
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_getlog(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct eth_priv_get_log *stats = NULL;
struct ifreq ifr;
struct timeval tv;
int i = 0;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: getlog fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
gettimeofday(&tv, NULL);
/* Process results */
stats = (struct eth_priv_get_log *)buffer;
printf("Get log: timestamp %d.%06d sec\n", (int)tv.tv_sec,
(int)tv.tv_usec);
printf("dot11GroupTransmittedFrameCount %u\n"
"dot11FailedCount %u\n"
"dot11RetryCount %u\n"
"dot11MultipleRetryCount %u\n"
"dot11FrameDuplicateCount %u\n"
"dot11RTSSuccessCount %u\n"
"dot11RTSFailureCount %u\n"
"dot11ACKFailureCount %u\n"
"dot11ReceivedFragmentCount %u\n"
"dot11GroupReceivedFrameCount %u\n"
"dot11FCSErrorCount %u\n"
"dot11TransmittedFrameCount %u\n"
"wepicverrcnt-1 %u\n"
"wepicverrcnt-2 %u\n"
"wepicverrcnt-3 %u\n"
"wepicverrcnt-4 %u\n"
"beaconReceivedCount %u\n"
"beaconMissedCount %u\n", stats->mcast_tx_frame,
stats->failed, stats->retry, stats->multi_retry,
stats->frame_dup, stats->rts_success, stats->rts_failure,
stats->ack_failure, stats->rx_frag, stats->mcast_rx_frame,
stats->fcs_error, stats->tx_frame, stats->wep_icv_error[0],
stats->wep_icv_error[1], stats->wep_icv_error[2],
stats->wep_icv_error[3], stats->bcn_rcv_cnt,
stats->bcn_miss_cnt);
if (cmd->used_len == sizeof(struct eth_priv_get_log)) {
printf("dot11TransmittedFragmentCount %u\n",
stats->tx_frag_cnt);
printf("dot11QosTransmittedFragmentCount ");
for (i = 0; i < 8; i++) {
printf("%u ", stats->qos_tx_frag_cnt[i]);
}
printf("\ndot11QosFailedCount ");
for (i = 0; i < 8; i++) {
printf("%u ", stats->qos_failed_cnt[i]);
}
printf("\ndot11QosRetryCount ");
for (i = 0; i < 8; i++) {
printf("%u ", stats->qos_retry_cnt[i]);
}
printf("\ndot11QosMultipleRetryCount ");
for (i = 0; i < 8; i++) {
printf("%u ", stats->qos_multi_retry_cnt[i]);
}
printf("\ndot11QosFrameDuplicateCount ");
for (i = 0; i < 8; i++) {
printf("%u ", stats->qos_frm_dup_cnt[i]);
}
printf("\ndot11QosRTSSuccessCount ");
for (i = 0; i < 8; i++) {
printf("%u ", stats->qos_rts_suc_cnt[i]);
}
printf("\ndot11QosRTSFailureCount ");
for (i = 0; i < 8; i++) {
printf("%u ", stats->qos_rts_failure_cnt[i]);
}
printf("\ndot11QosACKFailureCount ");
for (i = 0; i < 8; i++) {
printf("%u ", stats->qos_ack_failure_cnt[i]);
}
printf("\ndot11QosReceivedFragmentCount ");
for (i = 0; i < 8; i++) {
printf("%u ", stats->qos_rx_frag_cnt[i]);
}
printf("\ndot11QosTransmittedFrameCount ");
for (i = 0; i < 8; i++) {
printf("%u ", stats->qos_tx_frm_cnt[i]);
}
printf("\ndot11QosDiscardedFrameCount ");
for (i = 0; i < 8; i++) {
printf("%u ", stats->qos_discarded_frm_cnt[i]);
}
printf("\ndot11QosMPDUsReceivedCount ");
for (i = 0; i < 8; i++) {
printf("%u ", stats->qos_mpdus_rx_cnt[i]);
}
printf("\ndot11QosRetriesReceivedCount ");
for (i = 0; i < 8; i++) {
printf("%u ", stats->qos_retries_rx_cnt[i]);
}
printf("\ndot11RSNAStatsCMACICVErrors %u\n"
"dot11RSNAStatsCMACReplays %u\n"
"dot11RSNAStatsRobustMgmtCCMPReplays %u\n"
"dot11RSNAStatsTKIPICVErrors %u\n"
"dot11RSNAStatsTKIPReplays %u\n"
"dot11RSNAStatsCCMPDecryptErrors %u\n"
"dot11RSNAstatsCCMPReplays %u\n"
"dot11TransmittedAMSDUCount %u\n"
"dot11FailedAMSDUCount %u\n"
"dot11RetryAMSDUCount %u\n"
"dot11MultipleRetryAMSDUCount %u\n"
"dot11TransmittedOctetsInAMSDUCount %llu\n"
"dot11AMSDUAckFailureCount %u\n"
"dot11ReceivedAMSDUCount %u\n"
"dot11ReceivedOctetsInAMSDUCount %llu\n"
"dot11TransmittedAMPDUCount %u\n"
"dot11TransmittedMPDUsInAMPDUCount %u\n"
"dot11TransmittedOctetsInAMPDUCount %llu\n"
"dot11AMPDUReceivedCount %u\n"
"dot11MPDUInReceivedAMPDUCount %u\n"
"dot11ReceivedOctetsInAMPDUCount %llu\n"
"dot11AMPDUDelimiterCRCErrorCount %u\n",
stats->cmacicv_errors,
stats->cmac_replays,
stats->mgmt_ccmp_replays,
stats->tkipicv_errors,
stats->tkip_replays,
stats->ccmp_decrypt_errors,
stats->ccmp_replays,
stats->tx_amsdu_cnt,
stats->failed_amsdu_cnt,
stats->retry_amsdu_cnt,
stats->multi_retry_amsdu_cnt,
stats->tx_octets_in_amsdu_cnt,
stats->amsdu_ack_failure_cnt,
stats->rx_amsdu_cnt,
stats->rx_octets_in_amsdu_cnt,
stats->tx_ampdu_cnt,
stats->tx_mpdus_in_ampdu_cnt,
stats->tx_octets_in_ampdu_cnt,
stats->ampdu_rx_cnt,
stats->mpdu_in_rx_ampdu_cnt,
stats->rx_octets_in_ampdu_cnt,
stats->ampdu_delimiter_crc_error_cnt);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process esuppmode command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_esuppmode(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct eth_priv_esuppmode_cfg *esuppmodecfg = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: esuppmode fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
esuppmodecfg = (struct eth_priv_esuppmode_cfg *)buffer;
if (argc == 3) {
/* GET operation */
printf("Esupplicant Mode Configuration: \n");
/* RSN mode */
printf(" RSN mode: 0x%x ( ", esuppmodecfg->rsn_mode);
if (esuppmodecfg->rsn_mode & MBIT(0))
printf("No-RSN ");
if (esuppmodecfg->rsn_mode & MBIT(3))
printf("WPA ");
if (esuppmodecfg->rsn_mode & MBIT(4))
printf("WPA-None ");
if (esuppmodecfg->rsn_mode & MBIT(5))
printf("WPA2 ");
printf(")\n");
/* Pairwise cipher */
printf(" Pairwise cipher: 0x%x ( ",
esuppmodecfg->pairwise_cipher);
if (esuppmodecfg->pairwise_cipher & MBIT(2))
printf("TKIP ");
if (esuppmodecfg->pairwise_cipher & MBIT(3))
printf("AES ");
printf(")\n");
/* Group cipher */
printf(" Group cipher: 0x%x ( ",
esuppmodecfg->group_cipher);
if (esuppmodecfg->group_cipher & MBIT(2))
printf("TKIP ");
if (esuppmodecfg->group_cipher & MBIT(3))
printf("AES ");
printf(")\n");
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process passphrase command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_passphrase(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* The argument being a string, this requires special handling */
prepare_buffer(buffer, argv[2], 0, NULL);
if (argc >= 4) {
strcpy((char *)(buffer + strlen(CMD_MARVELL) + strlen(argv[2])),
argv[3]);
}
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: passphrase fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
printf("Passphrase Configuration: %s\n", (char *)buffer);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process deauth command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_deauth(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* The argument being a string, this requires special handling */
prepare_buffer(buffer, argv[2], 0, NULL);
if (argc >= 4) {
strcpy((char *)(buffer + strlen(CMD_MARVELL) + strlen(argv[2])),
argv[3]);
}
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: deauth fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
#ifdef UAP_SUPPORT
/**
* @brief Process getstalist command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_getstalist(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
struct eth_priv_getstalist *list = NULL;
int i = 0, rssi = 0;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* The argument being a string, this requires special handling */
prepare_buffer(buffer, argv[2], 0, NULL);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: getstalist fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
list = (struct eth_priv_getstalist *)(buffer + strlen(CMD_MARVELL) +
strlen(argv[2]));
printf("Number of STA = %d\n\n", list->sta_count);
for (i = 0; i < list->sta_count; i++) {
printf("STA %d information:\n", i + 1);
printf("=====================\n");
printf("MAC Address: ");
print_mac(list->client_info[i].mac_address);
printf("\nPower mfg status: %s\n",
(list->client_info[i].power_mfg_status ==
0) ? "active" : "power save");
/** On some platform, s8 is same as unsigned char*/
rssi = (int)list->client_info[i].rssi;
if (rssi > 0x7f)
rssi = -(256 - rssi);
printf("Rssi : %d dBm\n\n", rssi);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
#endif
#if defined(WIFI_DIRECT_SUPPORT)
#if defined(STA_SUPPORT) && defined(UAP_SUPPORT)
/**
* @brief Process BSS role command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_bssrole(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: bssrole fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
if (argc == 3) {
/* GET operation */
printf("BSS role: %d\n", buffer[0]);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
#endif
#endif
#ifdef STA_SUPPORT
/**
* @brief Helper function for process_getscantable_idx
*
* @param pbuf A pointer to the buffer
* @param buf_len Buffer length
*
* @return NA
*
*/
static void
dump_scan_elems(const t_u8 *pbuf, uint buf_len)
{
uint idx;
uint marker = 2 + pbuf[1];
for (idx = 0; idx < buf_len; idx++) {
if (idx % 0x10 == 0) {
printf("\n%04x: ", idx);
}
if (idx == marker) {
printf("|");
marker = idx + pbuf[idx + 1] + 2;
} else {
printf(" ");
}
printf("%02x ", pbuf[idx]);
}
printf("\n");
}
/**
* @brief Helper function for process_getscantable_idx
* Find next element
*
* @param pp_ie_out Pointer of a IEEEtypes_Generic_t structure pointer
* @param p_buf_left Integer pointer, which contains the number of left p_buf
*
* @return MLAN_STATUS_SUCCESS on success, otherwise MLAN_STATUS_FAILURE
*/
static int
scantable_elem_next(IEEEtypes_Generic_t **pp_ie_out, int *p_buf_left)
{
IEEEtypes_Generic_t *pie_gen;
t_u8 *p_next;
if (*p_buf_left < 2) {
return MLAN_STATUS_FAILURE;
}
pie_gen = *pp_ie_out;
p_next = (t_u8 *)pie_gen + (pie_gen->ieee_hdr.len
+ sizeof(pie_gen->ieee_hdr));
*p_buf_left -= (p_next - (t_u8 *)pie_gen);
*pp_ie_out = (IEEEtypes_Generic_t *)p_next;
if (*p_buf_left <= 0) {
return MLAN_STATUS_FAILURE;
}
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Helper function for process_getscantable_idx
* scantable find element
*
* @param ie_buf Pointer of the IE buffer
* @param ie_buf_len IE buffer length
* @param ie_type IE type
* @param ppie_out Pointer to the IEEEtypes_Generic_t structure pointer
* @return MLAN_STATUS_SUCCESS on success, otherwise MLAN_STATUS_FAILURE
*/
static int
scantable_find_elem(t_u8 *ie_buf,
unsigned int ie_buf_len,
IEEEtypes_ElementId_e ie_type,
IEEEtypes_Generic_t **ppie_out)
{
int found;
unsigned int ie_buf_left;
ie_buf_left = ie_buf_len;
found = FALSE;
*ppie_out = (IEEEtypes_Generic_t *)ie_buf;
do {
found = ((*ppie_out)->ieee_hdr.element_id == ie_type);
} while (!found &&
(scantable_elem_next(ppie_out, (int *)&ie_buf_left) == 0));
if (!found) {
*ppie_out = NULL;
}
return found ? MLAN_STATUS_SUCCESS : MLAN_STATUS_FAILURE;
}
/**
* @brief Helper function for process_getscantable_idx
* It gets SSID from IE
*
* @param ie_buf IE buffer
* @param ie_buf_len IE buffer length
* @param pssid SSID
* @param ssid_buf_max Size of SSID
* @return MLAN_STATUS_SUCCESS on success, otherwise MLAN_STATUS_FAILURE
*/
static int
scantable_get_ssid_from_ie(t_u8 *ie_buf,
unsigned int ie_buf_len,
t_u8 *pssid, unsigned int ssid_buf_max)
{
int retval;
IEEEtypes_Generic_t *pie_gen;
retval = scantable_find_elem(ie_buf, ie_buf_len, SSID, &pie_gen);
if (retval == MLAN_STATUS_SUCCESS)
memcpy(pssid, pie_gen->data,
MIN(pie_gen->ieee_hdr.len, ssid_buf_max));
else
return MLAN_STATUS_FAILURE;
return retval;
}
/**
* @brief Display detailed information for a specific scan table entry
*
* @param cmd_name Command name
* @param prsp_info_req Scan table entry request structure
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
int
process_getscantable_idx(char *cmd_name,
wlan_ioctl_get_scan_table_info *prsp_info_req)
{
int ret = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
t_u8 *pcurrent;
char ssid[33];
t_u16 tmp_cap;
t_u8 tsf[8];
t_u16 beacon_interval;
t_u16 cap_info;
wlan_ioctl_get_scan_table_info *prsp_info;
wlan_get_scan_table_fixed fixed_fields;
t_u32 fixed_field_length;
t_u32 bss_info_length;
memset(ssid, 0x00, sizeof(ssid));
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, cmd_name, 0, NULL);
prsp_info =
(wlan_ioctl_get_scan_table_info *)(buffer +
strlen(CMD_MARVELL) +
strlen(cmd_name));
memcpy(prsp_info, prsp_info_req,
sizeof(wlan_ioctl_get_scan_table_info));
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/*
* Set up and execute the ioctl call
*/
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
if (errno == EAGAIN) {
ret = -EAGAIN;
} else {
perror("mlanutl");
fprintf(stderr, "mlanutl: getscantable fail\n");
ret = MLAN_STATUS_FAILURE;
}
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return ret;
}
prsp_info = (wlan_ioctl_get_scan_table_info *)buffer;
if (prsp_info->scan_number == 0) {
printf("mlanutl: getscantable ioctl - index out of range\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return -EINVAL;
}
pcurrent = prsp_info->scan_table_entry_buf;
memcpy((t_u8 *)&fixed_field_length,
(t_u8 *)pcurrent, sizeof(fixed_field_length));
pcurrent += sizeof(fixed_field_length);
memcpy((t_u8 *)&bss_info_length,
(t_u8 *)pcurrent, sizeof(bss_info_length));
pcurrent += sizeof(bss_info_length);
memcpy((t_u8 *)&fixed_fields, (t_u8 *)pcurrent, sizeof(fixed_fields));
pcurrent += fixed_field_length;
/* Time stamp is 8 byte long */
memcpy(tsf, pcurrent, sizeof(tsf));
pcurrent += sizeof(tsf);
bss_info_length -= sizeof(tsf);
/* Beacon interval is 2 byte long */
memcpy(&beacon_interval, pcurrent, sizeof(beacon_interval));
pcurrent += sizeof(beacon_interval);
bss_info_length -= sizeof(beacon_interval);
/* Capability information is 2 byte long */
memcpy(&cap_info, pcurrent, sizeof(cap_info));
pcurrent += sizeof(cap_info);
bss_info_length -= sizeof(cap_info);
scantable_get_ssid_from_ie(pcurrent,
bss_info_length, (t_u8 *)ssid, sizeof(ssid));
printf("\n*** [%s], %02x:%02x:%02x:%02x:%02x:%2x\n",
ssid,
fixed_fields.bssid[0],
fixed_fields.bssid[1],
fixed_fields.bssid[2],
fixed_fields.bssid[3],
fixed_fields.bssid[4], fixed_fields.bssid[5]);
memcpy(&tmp_cap, &cap_info, sizeof(tmp_cap));
printf("Channel = %d, SS = %d, CapInfo = 0x%04x, BcnIntvl = %d\n",
fixed_fields.channel,
255 - fixed_fields.rssi, tmp_cap, beacon_interval);
printf("TSF Values: AP(0x%02x%02x%02x%02x%02x%02x%02x%02x), ",
tsf[7], tsf[6], tsf[5], tsf[4], tsf[3], tsf[2], tsf[1], tsf[0]);
printf("Network(0x%016llx)\n", fixed_fields.network_tsf);
printf("\n");
printf("Element Data (%d bytes)\n", (int)bss_info_length);
printf("------------");
dump_scan_elems(pcurrent, bss_info_length);
printf("\n");
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief channel validation.
* @param scan_req A pointer to wlan_ioctl_user_scan_cfg structure
* @param chan_num channel number
*
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
int
wlan_is_channel_valid(wlan_ioctl_user_scan_cfg *scan_req, t_u8 chan_number)
{
int ret = -1;
int i;
if (scan_req && scan_req->chan_list[0].chan_number) {
for (i = 0;
i < WLAN_IOCTL_USER_SCAN_CHAN_MAX &&
scan_req->chan_list[i].chan_number; i++) {
if (scan_req->chan_list[i].chan_number == chan_number) {
ret = 0;
break;
}
}
} else {
ret = 0;
}
return ret;
}
/**
* @brief filter_ssid_result
* @param scan_req A pointer to wlan_ioctl_user_scan_cfg structure
* @param num_ssid_rqst Number of SSIDs which are filterted
* @param bss_info A pointer to current bss information structure
* @return 0--success, otherwise--fail
*/
int
filter_ssid_result(wlan_ioctl_user_scan_cfg *scan_req, int num_ssid_rqst,
wlan_ioctl_get_bss_info *bss_info)
{
int i, ret = 1;
for (i = 0; i < num_ssid_rqst; i++) {
if ((memcmp(scan_req->ssid_list[i].ssid, bss_info->ssid,
(int)bss_info->ssid_len)) == 0) {
return 0;
}
}
return ret;
}
/**
* @brief Process getscantable command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @param scan_req A pointer to wlan_ioctl_user_scan_cfg structure
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
wlan_process_getscantable(int argc, char *argv[],
wlan_ioctl_user_scan_cfg *scan_req)
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
struct wlan_ioctl_get_scan_list *scan_list_head = NULL;
struct wlan_ioctl_get_scan_list *scan_list_node = NULL;
struct wlan_ioctl_get_scan_list *curr = NULL, *next = NULL;
t_u32 total_scan_res = 0;
unsigned int scan_start;
int idx, ret = 0;
t_u8 *pcurrent;
t_u8 *pnext;
IEEEtypes_ElementId_e *pelement_id;
t_u8 *pelement_len;
int ssid_idx;
int insert = 0;
int sort_by_channel = 0;
t_u8 *pbyte;
t_u16 new_ss = 0;
t_u16 curr_ss = 0;
t_u8 new_ch = 0;
t_u8 curr_ch = 0;
IEEEtypes_VendorSpecific_t *pwpa_ie;
const t_u8 wpa_oui[4] = { 0x00, 0x50, 0xf2, 0x01 };
IEEEtypes_WmmParameter_t *pwmm_ie;
const t_u8 wmm_oui[4] = { 0x00, 0x50, 0xf2, 0x02 };
IEEEtypes_VendorSpecific_t *pwps_ie;
const t_u8 wps_oui[4] = { 0x00, 0x50, 0xf2, 0x04 };
int displayed_info;
wlan_ioctl_get_scan_table_info rsp_info_req;
wlan_ioctl_get_scan_table_info *prsp_info;
wlan_get_scan_table_fixed fixed_fields;
t_u32 fixed_field_length;
t_u32 bss_info_length;
wlan_ioctl_get_bss_info *bss_info;
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
if (argc > 3 && (strcmp(argv[3], "tsf") != 0)
&& (strcmp(argv[3], "help") != 0)
&& (strcmp(argv[3], "ch") != 0)) {
idx = strtol(argv[3], NULL, 10);
if (idx >= 0) {
rsp_info_req.scan_number = idx;
ret = process_getscantable_idx(argv[2], &rsp_info_req);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
}
displayed_info = FALSE;
scan_start = 1;
do {
prepare_buffer(buffer, argv[2], 0, NULL);
prsp_info =
(wlan_ioctl_get_scan_table_info *)(buffer +
strlen(CMD_MARVELL) +
strlen(argv[2]));
prsp_info->scan_number = scan_start;
/*
* Set up and execute the ioctl call
*/
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
if (errno == EAGAIN) {
ret = -EAGAIN;
} else {
perror("mlanutl");
fprintf(stderr, "mlanutl: getscantable fail\n");
ret = MLAN_STATUS_FAILURE;
}
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return ret;
}
prsp_info = (wlan_ioctl_get_scan_table_info *)buffer;
pcurrent = 0;
pnext = prsp_info->scan_table_entry_buf;
total_scan_res += prsp_info->scan_number;
for (idx = 0; (unsigned int)idx < prsp_info->scan_number; idx++) {
/* Alloc memory for new node for next BSS */
scan_list_node = (struct wlan_ioctl_get_scan_list *)
malloc(sizeof(struct wlan_ioctl_get_scan_list));
if (scan_list_node == NULL) {
printf("Error: allocate memory for scan_list_head failed\n");
return -ENOMEM;
}
memset(scan_list_node, 0,
sizeof(struct wlan_ioctl_get_scan_list));
/*
* Set pcurrent to pnext in case pad bytes are at the end
* of the last IE we processed.
*/
pcurrent = pnext;
/* Start extracting each BSS to prepare a linked list */
memcpy((t_u8 *)&fixed_field_length,
(t_u8 *)pcurrent, sizeof(fixed_field_length));
pcurrent += sizeof(fixed_field_length);
memcpy((t_u8 *)&bss_info_length,
(t_u8 *)pcurrent, sizeof(bss_info_length));
pcurrent += sizeof(bss_info_length);
memcpy((t_u8 *)&fixed_fields,
(t_u8 *)pcurrent, sizeof(fixed_fields));
pcurrent += fixed_field_length;
scan_list_node->fixed_buf.fixed_field_length =
fixed_field_length;
scan_list_node->fixed_buf.bss_info_length =
bss_info_length;
scan_list_node->fixed_buf.fixed_fields = fixed_fields;
bss_info = &scan_list_node->bss_info_buf;
/* Set next to be the start of the next scan entry */
pnext = pcurrent + bss_info_length;
if (bss_info_length >=
(sizeof(bss_info->tsf) +
sizeof(bss_info->beacon_interval) +
sizeof(bss_info->cap_info))) {
/* time stamp is 8 byte long */
memcpy(bss_info->tsf, pcurrent,
sizeof(bss_info->tsf));
pcurrent += sizeof(bss_info->tsf);
bss_info_length -= sizeof(bss_info->tsf);
/* beacon interval is 2 byte long */
memcpy(&bss_info->beacon_interval, pcurrent,
sizeof(bss_info->beacon_interval));
pcurrent += sizeof(bss_info->beacon_interval);
bss_info_length -=
sizeof(bss_info->beacon_interval);
/* capability information is 2 byte long */
memcpy(&bss_info->cap_info, pcurrent,
sizeof(bss_info->cap_info));
pcurrent += sizeof(bss_info->cap_info);
bss_info_length -= sizeof(bss_info->cap_info);
}
bss_info->wmm_cap = ' '; /* M (WMM), C (WMM-Call Admission Control) */
bss_info->wps_cap = ' '; /* "S" */
bss_info->dot11k_cap = ' '; /* "K" */
bss_info->dot11r_cap = ' '; /* "R" */
bss_info->ht_cap = ' '; /* "N" */
bss_info->vht_cap[0] = 'A';
bss_info->vht_cap[1] = 'C';
/* "P" for Privacy (WEP) since "W" is WPA, and "2" is RSN/WPA2 */
bss_info->priv_cap =
bss_info->cap_info.privacy ? 'P' : ' ';
memset(bss_info->ssid, 0, MRVDRV_MAX_SSID_LENGTH + 1);
bss_info->ssid_len = 0;
while (bss_info_length >= 2) {
pelement_id = (IEEEtypes_ElementId_e *)pcurrent;
pelement_len = pcurrent + 1;
pcurrent += 2;
if ((bss_info_length - 2) < *pelement_len) {
printf("Error when processing bss info, bss_info_length < element length\n");
bss_info_length = 0;
continue;
}
switch (*pelement_id) {
case SSID:
if (*pelement_len &&
*pelement_len <=
MRVDRV_MAX_SSID_LENGTH) {
memcpy(bss_info->ssid, pcurrent,
*pelement_len);
bss_info->ssid_len =
*pelement_len;
}
break;
case WPA_IE:
pwpa_ie =
(IEEEtypes_VendorSpecific_t *)
pelement_id;
if ((memcmp
(pwpa_ie->vend_hdr.oui, wpa_oui,
sizeof(pwpa_ie->vend_hdr.oui)) ==
0)
&& (pwpa_ie->vend_hdr.oui_type ==
wpa_oui[3])) {
/* WPA IE found, 'W' for WPA */
bss_info->priv_cap = 'W';
} else {
pwmm_ie =
(IEEEtypes_WmmParameter_t
*)pelement_id;
if ((memcmp
(pwmm_ie->vend_hdr.oui,
wmm_oui,
sizeof(pwmm_ie->vend_hdr.
oui)) == 0)
&& (pwmm_ie->vend_hdr.
oui_type ==
wmm_oui[3])) {
/* Check the subtype: 1 == parameter, 0 == info */
if ((pwmm_ie->vend_hdr.
oui_subtype == 1)
&& pwmm_ie->
ac_params
[WMM_AC_VO].
aci_aifsn.acm) {
/* Call admission on VO; 'C' for CAC */
bss_info->
wmm_cap
= 'C';
} else {
/* No CAC; 'M' for uh, WMM */
bss_info->
wmm_cap
= 'M';
}
} else {
pwps_ie =
(IEEEtypes_VendorSpecific_t
*)pelement_id;
if ((memcmp
(pwps_ie->vend_hdr.
oui, wps_oui,
sizeof(pwps_ie->
vend_hdr.
oui)) == 0)
&& (pwps_ie->
vend_hdr.
oui_type ==
wps_oui[3])) {
bss_info->
wps_cap
= 'S';
}
}
}
break;
case RSN_IE:
/* RSN IE found; '2' for WPA2 (RSN) */
bss_info->priv_cap = '2';
break;
case HT_CAPABILITY:
bss_info->ht_cap = 'N';
break;
case VHT_CAPABILITY:
bss_info->vht_cap[0] = 'A';
bss_info->vht_cap[1] = 'C';
break;
default:
break;
}
pcurrent += *pelement_len;
bss_info_length -= (2 + *pelement_len);
}
/* Create a sorted list of BSS using Insertion Sort. */
if ((argc > 3) && !strcmp(argv[3], "ch")) {
/* Sort by channel number (ascending order) */
new_ch = fixed_fields.channel;
sort_by_channel = 1;
} else {
/* Sort as per Signal Strength (descending order) (Default case) */
new_ss = 255 - fixed_fields.rssi;
}
if (scan_list_head == NULL) {
/* Node is the first element in the list. */
scan_list_head = scan_list_node;
scan_list_node->next = NULL;
scan_list_node->prev = NULL;
} else {
curr = scan_list_head;
insert = 0;
do {
if (sort_by_channel) {
curr_ch =
curr->fixed_buf.
fixed_fields.channel;
if (new_ch < curr_ch)
insert = 1;
} else {
curr_ss =
255 -
curr->fixed_buf.
fixed_fields.rssi;
if (new_ss > curr_ss) {
insert = 1;
}
}
if (insert) {
if (curr == scan_list_head) {
/* Insert the node to head of the list */
scan_list_node->next =
scan_list_head;
scan_list_head->prev =
scan_list_node;
scan_list_head =
scan_list_node;
} else {
/* Insert the node to current position in list */
scan_list_node->prev =
curr->prev;
scan_list_node->next =
curr;
(curr->prev)->next =
scan_list_node;
curr->prev =
scan_list_node;
}
break;
}
if (curr->next == NULL) {
/* Insert the node to tail of the list */
curr->next = scan_list_node;
scan_list_node->prev = curr;
scan_list_node->next = NULL;
break;
}
curr = curr->next;
} while (curr != NULL);
}
}
scan_start += prsp_info->scan_number;
} while (prsp_info->scan_number);
/* Display scan results */
printf("---------------------------------------");
printf("---------------------------------------\n");
printf("# | ch | ss | bssid | cap | SSID \n");
printf("---------------------------------------");
printf("---------------------------------------\n");
for (curr = scan_list_head, idx = 0;
(curr != NULL) && ((unsigned int)idx < total_scan_res);
curr = curr->next, idx++) {
fixed_fields = curr->fixed_buf.fixed_fields;
bss_info = &curr->bss_info_buf;
if (wlan_is_channel_valid(scan_req, fixed_fields.channel))
continue;
if (setuserscan_filter == BSSID_FILTER) {
if (memcmp
(scan_req->specific_bssid, fixed_fields.bssid,
ETH_ALEN))
continue;
}
if (setuserscan_filter == SSID_FILTER) {
if (filter_ssid_result
(scan_req, num_ssid_filter, bss_info))
continue;
}
printf("%02u| %03d | %03d | %02x:%02x:%02x:%02x:%02x:%02x |",
idx,
fixed_fields.channel,
-fixed_fields.rssi,
fixed_fields.bssid[0],
fixed_fields.bssid[1],
fixed_fields.bssid[2],
fixed_fields.bssid[3],
fixed_fields.bssid[4], fixed_fields.bssid[5]);
displayed_info = TRUE;
/* "A" for Adhoc
* "I" for Infrastructure,
* "D" for DFS (Spectrum Mgmt)
*/
printf(" %c%c%c%c%c%c%c%c%c%c | ", bss_info->cap_info.ibss ? 'A' : 'I', bss_info->priv_cap, /* P (WEP), W (WPA), 2 (WPA2) */
bss_info->cap_info.spectrum_mgmt ? 'D' : ' ', bss_info->wmm_cap, /* M (WMM), C (WMM-Call Admission Control) */
bss_info->dot11k_cap, /* K */
bss_info->dot11r_cap, /* R */
bss_info->wps_cap, /* S */
bss_info->ht_cap, /* N */
bss_info->vht_cap[0], /* AC */
bss_info->vht_cap[1]);
/* Print out the ssid or the hex values if non-printable */
for (ssid_idx = 0; ssid_idx < (int)bss_info->ssid_len;
ssid_idx++) {
if (isprint(bss_info->ssid[ssid_idx])) {
printf("%c", bss_info->ssid[ssid_idx]);
} else {
printf("\\%02x", bss_info->ssid[ssid_idx]);
}
}
printf("\n");
if (argc > 3 && strcmp(argv[3], "tsf") == 0) {
/* TSF is a u64, some formatted printing libs have trouble
printing long longs, so cast and dump as bytes */
pbyte = (t_u8 *)&fixed_fields.network_tsf;
printf(" TSF=%02x%02x%02x%02x%02x%02x%02x%02x\n",
pbyte[7], pbyte[6], pbyte[5], pbyte[4],
pbyte[3], pbyte[2], pbyte[1], pbyte[0]);
}
}
if (displayed_info == TRUE) {
if (argc > 3 && strcmp(argv[3], "help") == 0) {
printf("\n\n"
"Capability Legend (Not all may be supported)\n"
"-----------------\n"
" I [ Infrastructure ]\n"
" A [ Ad-hoc ]\n"
" W [ WPA IE ]\n"
" 2 [ WPA2/RSN IE ]\n"
" M [ WMM IE ]\n"
" C [ Call Admission Control - WMM IE, VO ACM set ]\n"
" D [ Spectrum Management - DFS (11h) ]\n"
" K [ 11k ]\n"
" R [ 11r ]\n"
" S [ WPS ]\n"
" N [ HT (11n) ]\n"
" AC [VHT (11ac) ]\n" "\n\n");
}
} else {
printf("< No Scan Results >\n");
}
for (curr = scan_list_head; curr != NULL; curr = next) {
next = curr->next;
free(curr);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process getscantable command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @param scan_req A pointer to wlan_ioctl_user_scan_cfg structure
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_getscantable(int argc, char *argv[])
{
return wlan_process_getscantable(argc, argv, NULL);
}
/**
* @brief Prepare setuserscan command buffer
* @param scan_req pointer to wlan_ioctl_user_scan_cfg structure
* @param num Number of arguments
* @param args Arguments list
* @return MLAN_STATUS_SUCCESS
*/
static int
prepare_setuserscan_buffer(wlan_ioctl_user_scan_cfg *scan_req, t_u32 num,
char *args[])
{
int arg_idx = 0;
int num_ssid = 0;
char *parg_tok = NULL;
char *pchan_tok = NULL;
char *parg_cookie = NULL;
char *pchan_cookie = NULL;
int chan_parse_idx = 0;
int chan_cmd_idx = 0;
char chan_scratch[MAX_CHAN_SCRATCH];
char *pscratch = NULL;
int tmp_idx = 0;
int scan_time = 0;
int is_radio_set = 0;
unsigned int mac[ETH_ALEN];
for (arg_idx = 0; arg_idx < (int)num; arg_idx++) {
if (strncmp(args[arg_idx], "ssid=", strlen("ssid=")) == 0) {
/* "ssid" token string handler */
if (num_ssid < MRVDRV_MAX_SSID_LIST_LENGTH) {
strncpy(scan_req->ssid_list[num_ssid].ssid,
args[arg_idx] + strlen("ssid="),
sizeof(scan_req->ssid_list[num_ssid].
ssid));
scan_req->ssid_list[num_ssid].max_len = 0;
setuserscan_filter = SSID_FILTER;
num_ssid++;
num_ssid_filter++;
}
} else if (strncmp(args[arg_idx], "bssid=", strlen("bssid=")) ==
0) {
/* "bssid" token string handler */
sscanf(args[arg_idx] + strlen("bssid="),
"%2x:%2x:%2x:%2x:%2x:%2x", mac + 0, mac + 1,
mac + 2, mac + 3, mac + 4, mac + 5);
setuserscan_filter = BSSID_FILTER;
for (tmp_idx = 0;
(unsigned int)tmp_idx < NELEMENTS(mac);
tmp_idx++) {
scan_req->specific_bssid[tmp_idx] =
(t_u8)mac[tmp_idx];
}
} else if (strncmp(args[arg_idx], "chan=", strlen("chan=")) ==
0) {
/* "chan" token string handler */
parg_tok = args[arg_idx] + strlen("chan=");
if (strlen(parg_tok) > MAX_CHAN_SCRATCH) {
printf("Error: Specified channels exceeds max limit\n");
return MLAN_STATUS_FAILURE;
}
is_radio_set = FALSE;
while ((parg_tok =
strtok_r(parg_tok, ",",
&parg_cookie)) != NULL) {
memset(chan_scratch, 0x00,
sizeof(chan_scratch));
pscratch = chan_scratch;
for (chan_parse_idx = 0;
(unsigned int)chan_parse_idx <
strlen(parg_tok); chan_parse_idx++) {
if (isalpha
(*(parg_tok + chan_parse_idx))) {
*pscratch++ = ' ';
}
*pscratch++ =
*(parg_tok + chan_parse_idx);
}
*pscratch = 0;
parg_tok = NULL;
pchan_tok = chan_scratch;
while ((pchan_tok = strtok_r(pchan_tok, " ",
&pchan_cookie)) !=
NULL) {
if (isdigit(*pchan_tok)) {
scan_req->
chan_list[chan_cmd_idx].
chan_number =
atoi(pchan_tok);
if (scan_req->
chan_list[chan_cmd_idx].
chan_number >
MAX_CHAN_BG_BAND)
scan_req->
chan_list
[chan_cmd_idx].
radio_type = 1;
} else {
switch (toupper(*pchan_tok)) {
case 'A':
scan_req->
chan_list
[chan_cmd_idx].
radio_type = 1;
is_radio_set = TRUE;
break;
case 'B':
case 'G':
scan_req->
chan_list
[chan_cmd_idx].
radio_type = 0;
is_radio_set = TRUE;
break;
case 'N':
break;
case 'C':
scan_req->
chan_list
[chan_cmd_idx].
scan_type =
MLAN_SCAN_TYPE_ACTIVE;
break;
case 'P':
scan_req->
chan_list
[chan_cmd_idx].
scan_type =
MLAN_SCAN_TYPE_PASSIVE;
break;
default:
printf("Error: Band type not supported!\n");
return -EOPNOTSUPP;
}
if (!chan_cmd_idx &&
!scan_req->
chan_list[chan_cmd_idx].
chan_number && is_radio_set)
scan_req->
chan_list
[chan_cmd_idx].
radio_type |=
BAND_SPECIFIED;
}
pchan_tok = NULL;
}
if (((scan_req->chan_list[chan_cmd_idx].
chan_number > MAX_CHAN_BG_BAND)
&& !scan_req->chan_list[chan_cmd_idx].
radio_type) ||
((scan_req->chan_list[chan_cmd_idx].
chan_number < MAX_CHAN_BG_BAND)
&& (scan_req->chan_list[chan_cmd_idx].
radio_type == 1))) {
printf("Error: Invalid Radio type: chan=%d radio_type=%d\n", scan_req->chan_list[chan_cmd_idx].chan_number, scan_req->chan_list[chan_cmd_idx].radio_type);
return MLAN_STATUS_FAILURE;
}
chan_cmd_idx++;
}
} else if (strncmp(args[arg_idx], "gap=", strlen("gap=")) == 0) {
scan_req->scan_chan_gap =
atoi(args[arg_idx] + strlen("gap="));
} else if (strncmp(args[arg_idx], "keep=", strlen("keep=")) ==
0) {
/* "keep" token string handler */
scan_req->keep_previous_scan =
atoi(args[arg_idx] + strlen("keep="));
} else if (strncmp(args[arg_idx], "dur=", strlen("dur=")) == 0) {
/* "dur" token string handler */
scan_time = atoi(args[arg_idx] + strlen("dur="));
scan_req->chan_list[0].scan_time = scan_time;
} else if (strncmp(args[arg_idx], "wc=", strlen("wc=")) == 0) {
if (num_ssid < MRVDRV_MAX_SSID_LIST_LENGTH) {
/* "wc" token string handler */
pscratch = strrchr(args[arg_idx], ',');
if (pscratch) {
*pscratch = 0;
pscratch++;
if (isdigit(*pscratch)) {
scan_req->ssid_list[num_ssid].
max_len =
atoi(pscratch);
} else {
scan_req->ssid_list[num_ssid].
max_len = *pscratch;
}
} else {
/* Standard wildcard matching */
scan_req->ssid_list[num_ssid].max_len =
0xFF;
}
strncpy(scan_req->ssid_list[num_ssid].ssid,
args[arg_idx] + strlen("wc="),
sizeof(scan_req->ssid_list[num_ssid].
ssid));
num_ssid++;
}
} else if (strncmp(args[arg_idx], "probes=", strlen("probes="))
== 0) {
/* "probes" token string handler */
scan_req->num_probes =
atoi(args[arg_idx] + strlen("probes="));
if (scan_req->num_probes > MAX_PROBES) {
fprintf(stderr, "Invalid probes (> %d)\n",
MAX_PROBES);
return -EOPNOTSUPP;
}
} else if (strncmp
(args[arg_idx], "bss_type=",
strlen("bss_type=")) == 0) {
/* "bss_type" token string handler */
scan_req->bss_mode =
atoi(args[arg_idx] + strlen("bss_type="));
switch (scan_req->bss_mode) {
case MLAN_SCAN_MODE_BSS:
case MLAN_SCAN_MODE_IBSS:
break;
case MLAN_SCAN_MODE_ANY:
default:
/* Set any unknown types to ANY */
scan_req->bss_mode = MLAN_SCAN_MODE_ANY;
break;
}
} else if (strncmp
(args[arg_idx], "scan_type=",
strlen("scan_type=")) == 0) {
/* "scan_type" token string handler */
scan_req->ext_scan_type =
atoi(args[arg_idx] + strlen("scan_type="));
}
}
/* Update all the channels to have the same scan time */
for (tmp_idx = 1; tmp_idx < chan_cmd_idx; tmp_idx++) {
scan_req->chan_list[tmp_idx].scan_time = scan_time;
}
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process setuserscan command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_setuserscan(int argc, char *argv[])
{
wlan_ioctl_user_scan_cfg *scan_req = NULL;
t_u8 *pos = NULL;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
int status = 0;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Flag it for our use */
pos = buffer;
strncpy((char *)pos, CMD_MARVELL, strlen(CMD_MARVELL));
pos += (strlen(CMD_MARVELL));
/* Insert command */
strncpy((char *)pos, (char *)argv[2], strlen(argv[2]));
pos += (strlen(argv[2]));
/* Insert arguments */
scan_req = (wlan_ioctl_user_scan_cfg *)pos;
if (prepare_setuserscan_buffer(scan_req, (argc - 3), &argv[3])) {
printf("ERR:Invalid parameter\n");
return MLAN_STATUS_FAILURE;
}
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: setuserscan fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (argc > 3) {
if (!strcmp(argv[3], "sort_by_ch")) {
argv[3] = "ch";
} else {
argc = 0;
}
}
do {
argv[2] = "getscantable";
status = wlan_process_getscantable(argc, argv, scan_req);
} while (status == -EAGAIN);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process extended capabilities configuration
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_extcapcfg(int argc, char *argv[])
{
t_u8 *buffer = NULL, ext_cap[9];
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
IEEEtypes_Header_t ie;
if (argc > 4) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX extcapcfg <extcapa>\n");
return MLAN_STATUS_FAILURE;
}
if (argc == 4 && MLAN_STATUS_FAILURE == ishexstring(argv[3])) {
printf("ERR:Only hex digits are allowed.\n");
printf("Syntax: ./mlanutl mlanX extcapcfg <extcapa>\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* Only insert command */
prepare_buffer(buffer, argv[2], 0, NULL);
if (argc == 4) {
if (!strncasecmp("0x", argv[3], 2))
argv[3] += 2;
if (strlen(argv[3]) > 2 * sizeof(ext_cap)) {
printf("ERR:Incorrect length of arguments.\n");
printf("Syntax: ./mlanutl mlanX extcapcfg <extcapa>\n");
return MLAN_STATUS_FAILURE;
}
memset(ext_cap, 0, sizeof(ext_cap));
ie.element_id = TLV_TYPE_EXTCAP;
ie.len = sizeof(ext_cap);
string2raw(argv[3], ext_cap);
memcpy(buffer + strlen(CMD_MARVELL) + strlen(argv[2]), &ie,
sizeof(ie));
memcpy(buffer + strlen(CMD_MARVELL) + strlen(argv[2]) +
sizeof(ie), ext_cap, sizeof(ext_cap));
}
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr,
"mlanutl: extended capabilities configure fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
hexdump("Extended capabilities", buffer + sizeof(IEEEtypes_Header_t),
((IEEEtypes_Header_t *)buffer)->len, ' ');
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Cancel ongoing scan
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_cancelscan(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
if (argc != 3) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX cancelscan\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* Only insert command */
prepare_buffer(buffer, argv[2], 0, NULL);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: cancel scan fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
#endif /* STA_SUPPORT */
/**
* @brief Process deep sleep configuration
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_deepsleep(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: deepsleep fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
printf("Deepsleep command response: %s\n", buffer);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process ipaddr command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_ipaddr(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* The argument being a string, this requires special handling */
prepare_buffer(buffer, argv[2], 0, NULL);
if (argc >= 4) {
strcpy((char *)(buffer + strlen(CMD_MARVELL) + strlen(argv[2])),
argv[3]);
}
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: ipaddr fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
printf("IP address Configuration: %s\n", (char *)buffer);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process otpuserdata command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_otpuserdata(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
if (argc < 4) {
printf("ERR:No argument\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: otpuserdata fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
hexdump("OTP user data: ", buffer,
MIN(cmd->used_len, a2hex_or_atoi(argv[3])), ' ');
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process countrycode setting
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_countrycode(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct eth_priv_countrycode *countrycode = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* The argument being a string, this requires special handling */
prepare_buffer(buffer, argv[2], 0, NULL);
if (argc >= 4) {
strcpy((char *)(buffer + strlen(CMD_MARVELL) + strlen(argv[2])),
argv[3]);
}
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: countrycode fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
countrycode = (struct eth_priv_countrycode *)buffer;
if (argc == 3) {
/* GET operation */
printf("Country code: %s\n", countrycode->country_code);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process TCP ACK enhancement configuration
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_tcpackenh(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: tcpackenh fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
printf("TCP Ack enhancement: ");
if (buffer[0])
printf("enabled.\n");
else
printf("disabled.\n");
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
#ifdef REASSOCIATION
/**
* @brief Process asynced essid setting
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_assocessid(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* The argument being a string, this requires special handling */
prepare_buffer(buffer, argv[2], 0, NULL);
if (argc >= 4) {
strcpy((char *)(buffer + strlen(CMD_MARVELL) + strlen(argv[2])),
argv[3]);
}
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: assocessid fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
printf("Set Asynced ESSID: %s\n", (char *)buffer);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
#endif
#ifdef STA_SUPPORT
/**
* @brief Process listen interval configuration
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_listeninterval(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: listen interval fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
if (argc == 3)
printf("Listen interval command response: %s\n", buffer);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process power save mode setting
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_psmode(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
int psmode = 0;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: psmode fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
psmode = *(int *)buffer;
printf("PS mode: %d\n", psmode);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
#endif
#ifdef DEBUG_LEVEL1
/**
* @brief Process driver debug configuration
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_drvdbg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
t_u32 drvdbg;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: drvdbg config fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
if (argc == 3) {
memcpy(&drvdbg, buffer, sizeof(drvdbg));
printf("drvdbg: 0x%08x\n", drvdbg);
#ifdef DEBUG_LEVEL2
printf("MINFO (%08x) %s\n", MINFO,
(drvdbg & MINFO) ? "X" : "");
printf("MWARN (%08x) %s\n", MWARN,
(drvdbg & MWARN) ? "X" : "");
printf("MENTRY (%08x) %s\n", MENTRY,
(drvdbg & MENTRY) ? "X" : "");
#endif
printf("MMPA_D (%08x) %s\n", MMPA_D,
(drvdbg & MMPA_D) ? "X" : "");
printf("MIF_D (%08x) %s\n", MIF_D,
(drvdbg & MIF_D) ? "X" : "");
printf("MFW_D (%08x) %s\n", MFW_D,
(drvdbg & MFW_D) ? "X" : "");
printf("MEVT_D (%08x) %s\n", MEVT_D,
(drvdbg & MEVT_D) ? "X" : "");
printf("MCMD_D (%08x) %s\n", MCMD_D,
(drvdbg & MCMD_D) ? "X" : "");
printf("MDAT_D (%08x) %s\n", MDAT_D,
(drvdbg & MDAT_D) ? "X" : "");
printf("MIOCTL (%08x) %s\n", MIOCTL,
(drvdbg & MIOCTL) ? "X" : "");
printf("MINTR (%08x) %s\n", MINTR,
(drvdbg & MINTR) ? "X" : "");
printf("MEVENT (%08x) %s\n", MEVENT,
(drvdbg & MEVENT) ? "X" : "");
printf("MCMND (%08x) %s\n", MCMND,
(drvdbg & MCMND) ? "X" : "");
printf("MDATA (%08x) %s\n", MDATA,
(drvdbg & MDATA) ? "X" : "");
printf("MERROR (%08x) %s\n", MERROR,
(drvdbg & MERROR) ? "X" : "");
printf("MFATAL (%08x) %s\n", MFATAL,
(drvdbg & MFATAL) ? "X" : "");
printf("MMSG (%08x) %s\n", MMSG, (drvdbg & MMSG) ? "X" : "");
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
#endif
/**
* @brief Process hscfg configuration
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_hscfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
struct eth_priv_hs_cfg *hscfg;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: hscfg fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
hscfg = (struct eth_priv_hs_cfg *)buffer;
if (argc == 3) {
/* GET operation */
printf("HS Configuration:\n");
printf(" Conditions: %d\n", (int)hscfg->conditions);
printf(" GPIO: %d\n", (int)hscfg->gpio);
printf(" GAP: %d\n", (int)hscfg->gap);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process hssetpara configuration
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_hssetpara(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: hssetpara fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process wakeup reason
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_wakeupresaon(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: get wakeup reason fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
printf("Get wakeup reason response: %s\n", buffer);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process hscfg management frame config
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_mgmtfilter(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
FILE *fp = NULL;
int ret = MLAN_STATUS_SUCCESS;
char line[256], cmdname[256], *pos = NULL, *filter = NULL;
int cmdname_found = 0, name_found = 0;
int ln = 0, i = 0, numEntries = 0, len = 0;
eth_priv_mgmt_frame_wakeup hs_mgmt_filter[2];
if (argc < 4) {
printf("Error: invalid no of arguments\n");
printf("Syntax: ./mlanutl mlanX mgmtfilter <mgmtfilter.conf>\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
pos = (char *)buffer;
strncpy((char *)pos, CMD_MARVELL, strlen(CMD_MARVELL));
pos += (strlen(CMD_MARVELL));
len += (strlen(CMD_MARVELL));
/* Insert command */
strncpy((char *)pos, argv[2], strlen(argv[2]));
pos += (strlen(argv[2]));
len += (strlen(argv[2]));
filter = pos;
cmdname_found = 0;
snprintf(cmdname, sizeof(cmdname), "%s={", argv[2]);
fp = fopen(argv[3], "r");
if (fp == NULL) {
fprintf(stderr, "Cannot open file %s\n", argv[3]);
ret = MLAN_STATUS_FAILURE;
if (buffer)
free(buffer);
goto done;
}
while ((pos = mlan_config_get_line(fp, line, sizeof(line), &ln))) {
if (strcmp(pos, cmdname) == 0) {
cmdname_found = 1;
snprintf(cmdname, sizeof(cmdname), "entry_num=");
name_found = 0;
while ((pos =
mlan_config_get_line(fp, line, sizeof(line),
&ln))) {
if (strncmp(pos, cmdname, strlen(cmdname)) == 0) {
name_found = 1;
numEntries =
a2hex_or_atoi(pos +
strlen(cmdname));
if (numEntries > 2) {
printf("mlanutl: NumEntries exceed max number.\
We support two entries in currently\n");
return MLAN_STATUS_FAILURE;
}
break;
}
}
if (!name_found) {
fprintf(stderr,
"mlanutl: NumEntries not found in file '%s'\n",
argv[3]);
break;
}
for (i = 0; i < numEntries; i++) {
snprintf(cmdname, sizeof(cmdname), "entry_%d={",
i);
name_found = 0;
while ((pos =
mlan_config_get_line(fp, line,
sizeof(line),
&ln))) {
if (strncmp
(pos, cmdname,
strlen(cmdname)) == 0) {
name_found = 1;
break;
}
}
if (!name_found) {
fprintf(stderr,
"mlanutl: %s not found in file '%s'\n",
cmdname, argv[3]);
break;
}
snprintf(cmdname, sizeof(cmdname), "action=");
name_found = 0;
while ((pos =
mlan_config_get_line(fp, line,
sizeof(line),
&ln))) {
if (strncmp
(pos, cmdname,
strlen(cmdname)) == 0) {
name_found = 1;
hs_mgmt_filter[i].action =
a2hex_or_atoi(pos +
strlen
(cmdname));
break;
}
}
if (!name_found) {
fprintf(stderr,
"mlanutl: %s not found in file '%s'\n",
cmdname, argv[3]);
break;
}
snprintf(cmdname, sizeof(cmdname), "type=");
name_found = 0;
while ((pos =
mlan_config_get_line(fp, line,
sizeof(line),
&ln))) {
if (strncmp
(pos, cmdname,
strlen(cmdname)) == 0) {
name_found = 1;
hs_mgmt_filter[i].type =
a2hex_or_atoi(pos +
strlen
(cmdname));
break;
}
}
if (!name_found) {
fprintf(stderr,
"mlanutl: %s not found in file '%s'\n",
cmdname, argv[3]);
break;
}
snprintf(cmdname, sizeof(cmdname),
"frame_mask=");
name_found = 0;
while ((pos =
mlan_config_get_line(fp, line,
sizeof(line),
&ln))) {
if (strncmp
(pos, cmdname,
strlen(cmdname)) == 0) {
name_found = 1;
hs_mgmt_filter[i].frame_mask =
a2hex_or_atoi(pos +
strlen
(cmdname));
break;
}
}
if (!name_found) {
fprintf(stderr,
"mlanutl: %s not found in file '%s'\n",
cmdname, argv[3]);
break;
}
}
break;
}
}
fclose(fp);
if (!cmdname_found) {
fprintf(stderr, "mlanutl: ipPkt data not found in file '%s'\n",
argv[3]);
free(buffer);
return MLAN_STATUS_FAILURE;
}
memcpy(filter, (t_u8 *)hs_mgmt_filter,
sizeof(eth_priv_mgmt_frame_wakeup) * numEntries);
len += sizeof(eth_priv_mgmt_frame_wakeup) * numEntries;
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = len;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: cloud keep alive fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
done:
return ret;
}
/**
* @brief Process scancfg configuration
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_scancfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
struct eth_priv_scan_cfg *scancfg;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: scancfg fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
scancfg = (struct eth_priv_scan_cfg *)buffer;
/* Show scan configure */
printf("Scan Configuration:\n");
printf(" Scan Type: %d (%s)\n", scancfg->scan_type,
(scancfg->scan_type == 1) ? "Active" : (scancfg->scan_type ==
2) ? "Passive" : "");
printf(" Scan Mode: %d (%s)\n", scancfg->scan_mode,
(scancfg->scan_mode == 1) ? "BSS" : (scancfg->scan_mode ==
2) ? "IBSS" : (scancfg->
scan_mode ==
3) ? "Any" :
"");
printf(" Scan Probes: %d (%s)\n", scancfg->scan_probe,
"per channel");
printf(" Specific Scan Time: %d ms\n",
scancfg->scan_time.specific_scan_time);
printf(" Active Scan Time: %d ms\n",
scancfg->scan_time.active_scan_time);
printf(" Passive Scan Time: %d ms\n",
scancfg->scan_time.passive_scan_time);
printf(" Passive to Active Scan: %d (%s)\n",
scancfg->passive_to_active_scan,
(scancfg->passive_to_active_scan ==
MLAN_PASS_TO_ACT_SCAN_EN) ? "Enable" : (scancfg->
passive_to_active_scan
==
MLAN_PASS_TO_ACT_SCAN_DIS)
? "Disable" : "");
printf(" Extended Scan Support: %d (%s)\n", scancfg->ext_scan,
(scancfg->ext_scan == 1) ? "No" : (scancfg->ext_scan ==
2) ? "Yes" : (scancfg->
ext_scan ==
3) ? "Enhanced"
: "");
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process warmreset command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_warmreset(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* The argument being a string, this requires special handling */
prepare_buffer(buffer, argv[2], 0, NULL);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: warmreset fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
static char *bandwidth[4] = { "20 MHz", "40 MHz", "80 MHz", "160 MHz" };
/**
* @brief Process txpowercfg command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_txpowercfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
struct eth_priv_power_cfg_ext *power_ext = NULL;
struct eth_priv_power_group *power_group = NULL;
int i = 0;
/* Initialize buffer */
buffer = (t_u8 *)malloc(2 * BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = 2 * BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: txpowercfg fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
power_ext = (struct eth_priv_power_cfg_ext *)buffer;
if (argc == 3) {
/* GET operation */
printf("Tx Power Configurations:\n");
for (i = 0; i < power_ext->num_pwr_grp; i++) {
power_group = &power_ext->power_group[i];
if (power_group->rate_format == MLAN_RATE_FORMAT_HT) {
if (power_group->bandwidth == MLAN_HT_BW20) {
power_group->first_rate_ind += 12;
power_group->last_rate_ind += 12;
} else if (power_group->bandwidth ==
MLAN_HT_BW40) {
power_group->first_rate_ind += 140;
power_group->last_rate_ind += 140;
}
}
printf(" Power Group %d: \n", i);
printf(" Bandwidth: %3s %s\n",
rate_format[power_group->rate_format],
bandwidth[power_group->bandwidth]);
if (power_group->rate_format == 2)
/** NSS */
printf(" NSS: %3d\n",
power_group->nss);
printf(" first rate index: %3d\n",
power_group->first_rate_ind);
printf(" last rate index: %3d\n",
power_group->last_rate_ind);
printf(" minimum power: %3d dBm\n",
power_group->power_min);
printf(" maximum power: %3d dBm\n",
power_group->power_max);
printf(" power step: %3d\n",
power_group->power_step);
printf("\n");
power_group++;
}
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process pscfg command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_pscfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
struct eth_priv_ds_ps_cfg *ps_cfg = NULL;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: pscfg fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
ps_cfg = (struct eth_priv_ds_ps_cfg *)buffer;
if (argc == 3) {
/* GET operation */
printf("PS Configurations:\n");
printf("%d", (int)ps_cfg->ps_null_interval);
printf(" %d", (int)ps_cfg->multiple_dtim_interval);
printf(" %d", (int)ps_cfg->listen_interval);
printf(" %d", (int)ps_cfg->bcn_miss_timeout);
printf(" %d", (int)ps_cfg->delay_to_ps);
printf(" %d", (int)ps_cfg->ps_mode);
printf("\n");
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process bcntimeoutcfg command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_bcntimeoutcfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
if (argc != 7) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX bcntimeoutcfg [l] [m] [o] [p]\n");
return -EINVAL;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return -ENOMEM;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return -ENOMEM;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: bcntimeoutcfg fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return -EFAULT;
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return 0;
}
/**
* @brief Process sleeppd configuration
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_sleeppd(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
int sleeppd = 0;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: sleeppd fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
sleeppd = *(int *)buffer;
if (argc == 3) {
/* GET operation */
printf("Sleep Period: %d ms\n", sleeppd);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process tx control configuration
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_txcontrol(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
t_u32 txcontrol = 0;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: txcontrol fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
txcontrol = *(t_u32 *)buffer;
if (argc == 3) {
/* GET operation */
printf("Tx control: 0x%x\n", txcontrol);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Performs the ioctl operation to send the command to driver.
* @param cmd_buf Pointer to the command buffer
* @param buf_size Size of the allocated command buffer
* @return MLAN_STATUS_SUCCESS or MLAN_STATUS_FAILURE
*/
static int
tdls_ioctl(t_u8 *cmd_buf, t_u16 buf_size)
{
struct ifreq ifr;
/* Initialize the ifr structure */
memset(&ifr, 0, sizeof(ifr));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd_buf;
/* Perform ioctl */
if (ioctl(sockfd, TDLS_IOCTL, &ifr)) {
perror("");
return MLAN_STATUS_FAILURE;
}
return MLAN_STATUS_SUCCESS;
}
/**
* @brief host tdls config
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_host_tdls_config(int argc, char *argv[])
{
host_tdls_cfg *param_buf = NULL;
char *line = NULL;
FILE *config_file = NULL;
int li = 0, ret = 0, i = 0, cmd_found = 0;
char *args[30], *pos = NULL;
t_u16 cmd_len = 0, tlv_len_supp_chan = 0;
t_u16 no_of_supp_chan_sub_band = 0, num_of_regulatory_class =
0, tlv_len_reg_class;
t_u8 *buffer = NULL;
tlvbuf_SupportedChannels_t *supp_chan = NULL;
tlvbuf_RegulatoryClass_t *reg_class = NULL;
/* Check arguments */
if (argc != 4) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX host_tdls_config <config/host_tdls.conf>\n");
printf("Syntax: ./mlanutl mlanX host_tdls_config <0/1> \n ");
exit(1);
}
cmd_len = sizeof(host_tdls_cfg);
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate memory!\n");
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
param_buf = (host_tdls_cfg *) buffer;
param_buf->action = ACTION_HOST_TDLS_CONFIG;
/* Check if file exists */
config_file = fopen(argv[3], "r");
if (config_file == NULL) {
printf("ERR:Incorrect arguments.\n");
printf("Syntax: ./mlanutl mlanX host_tdls_config <config/host_tdls.conf>\n");
exit(1);
}
line = (char *)malloc(MAX_CONFIG_LINE);
if (!line) {
printf("ERR:Cannot allocate memory for line\n");
goto done;
}
memset(line, 0, MAX_CONFIG_LINE);
/* Parse file and process */
while (config_get_line(line, MAX_CONFIG_LINE, config_file, &li, &pos)) {
parse_line(line, args);
if (!cmd_found && strncmp(args[0], argv[2], strlen(args[0])))
continue;
cmd_found = 1;
if (strcmp(args[0], "uapsd_support") == 0) {
param_buf->uapsd_support = (t_u8)A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "cs_support") == 0) {
param_buf->cs_support = (t_u8)A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "SupportedChannels") == 0) {
/* Append a new TLV */
supp_chan =
(tlvbuf_SupportedChannels_t *)(buffer +
cmd_len);
supp_chan->tag = TLV_TYPE_SUPPORTED_CHANNELS;
supp_chan->length = sizeof(tlvbuf_SupportedChannels_t)
- TLVHEADER_LEN;
tlv_len_supp_chan = sizeof(tlvbuf_SupportedChannels_t);
cmd_len += tlv_len_supp_chan;
} else if (strncmp(args[0], "FirstChannelNo", 14) == 0) {
supp_chan->subband[no_of_supp_chan_sub_band].
start_chan = atoi(args[1]);
} else if (strcmp(args[0], "NumberofSubBandChannels") == 0) {
supp_chan->subband[no_of_supp_chan_sub_band].num_chans =
atoi(args[1]);
no_of_supp_chan_sub_band++;
tlv_len_supp_chan +=
sizeof(IEEEtypes_SupportChan_Subband_t);
supp_chan->length +=
sizeof(IEEEtypes_SupportChan_Subband_t);
cmd_len += sizeof(IEEEtypes_SupportChan_Subband_t);
endian_convert_tlv_header_out(supp_chan);
} else if (strcmp(args[0], "SupportedRegulatoryClasses") == 0) {
/* Append a new TLV */
reg_class =
(tlvbuf_RegulatoryClass_t *)(buffer + cmd_len);
tlv_len_reg_class = sizeof(tlvbuf_RegulatoryClass_t);
reg_class->tag = TLV_TYPE_REGULATORY_CLASSES;
cmd_len += tlv_len_reg_class;
} else if (strcmp(args[0], "CurrentRegulatoryClass") == 0) {
reg_class->regulatory_class.cur_regulatory_class =
atoi(args[1]);
reg_class->length = 1;
} else if (strcmp(args[0], "NumofRegulatoryClasses") == 0) {
num_of_regulatory_class = atoi(args[1]);
reg_class->length += num_of_regulatory_class;
cmd_len += num_of_regulatory_class;
endian_convert_tlv_header_out(reg_class);
} else if (strcmp(args[0], "ListOfRegulatoryClasses") == 0) {
for (i = 0; i < num_of_regulatory_class; i++)
reg_class->regulatory_class.
regulatory_classes_list[i] =
(t_u8)A2HEXDECIMAL(args[i + 1]);
}
}
/* adjust for size of action and tlv_len, capInfo */
param_buf->tlv_len = cmd_len - sizeof(host_tdls_cfg);
hexdump("host_tdls_config", buffer, cmd_len, ' ');
/* Send collective command */
ret = tdls_ioctl((t_u8 *)buffer, cmd_len);
/* Process response */
if (ret == MLAN_STATUS_SUCCESS) {
printf("TDLS Info settings sucessfully set.\n");
} else {
printf("ERR:Could not set TDLS info configuration.\n");
}
done:
if (config_file)
fclose(config_file);
if (buffer)
free(buffer);
if (line)
free(line);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief enable/disable tdls config
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_tdls_config(int argc, char *argv[])
{
tdls_config *param_buf = NULL;
int ret = 0;
t_u16 cmd_len = 0;
t_u8 *buffer = NULL;
/* Check arguments */
if (argc != 4) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_config <0/1>\n");
exit(1);
}
cmd_len = sizeof(tdls_config);
buffer = (t_u8 *)malloc(cmd_len);
if (!buffer) {
printf("ERR:Cannot allocate memory!\n");
goto done;
}
memset(buffer, 0, cmd_len);
param_buf = (tdls_config *) buffer;
param_buf->action = ACTION_TDLS_CONFIG;
param_buf->data = (t_u16)A2HEXDECIMAL(argv[3]);
if ((param_buf->data != 0) && (param_buf->data != 1)) {
printf("ERR:Incorrect arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_config <0/1>\n");
goto done;
}
hexdump("tdls_config ", buffer, cmd_len, ' ');
/* Send collective command */
ret = tdls_ioctl((t_u8 *)buffer, cmd_len);
/* Process response */
if (ret == MLAN_STATUS_SUCCESS) {
printf("TDLS %s successful.\n",
(param_buf->data) ? "enable" : "disable");
} else {
printf("ERR:TDLS %s failed.\n",
(param_buf->data) ? "enable" : "disable");
}
done:
if (buffer)
free(buffer);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process tdls_setinfo
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_tdls_setinfo(int argc, char *argv[])
{
tdls_setinfo *param_buf = NULL;
char *line = NULL;
FILE *config_file = NULL;
int li = 0, arg_num = 0, ret = 0, i = 0, cmd_found = 0, pairwise_index =
0, akm_index = 0, pmkid_index = 0;
char *args[30], *pos = NULL;
t_u16 cmd_len = 0, tlv_len = 0, tlv_len_rsn = 0, tlv_len_supp_chan =
0, tlv_len_domain = 0;
t_u16 no_of_sub_band = 0, no_of_supp_chan_sub_band =
0, pairwise_offset = 0, akm_offset =
0, num_of_regulatory_class = 0, tlv_len_reg_class;
t_u16 akm_count = 0, pmk_count = 0, rsn_cap = 0;
t_u8 *buffer = NULL;
char country[COUNTRY_CODE_LEN];
tlvbuf_DomainParamSet_t *domain = NULL;
tlvbuf_SupportedChannels_t *supp_chan = NULL;
tlvbuf_RegulatoryClass_t *reg_class = NULL;
tlvbuf_HTCap_t *tlv_ht_cap = NULL;
tlvbuf_RsnParamSet_t *rsn_ie = NULL;
tlvbuf_HTInfo_t *tlv_ht_info = NULL;
t_u8 pairwise_cipher_suite[PAIRWISE_CIPHER_SUITE_LEN];
t_u8 akm_suite[AKM_SUITE_LEN];
t_u8 pmkid[PMKID_LEN];
tlvbuf_VHTCap_t *tlv_vht_cap = NULL;
tlvbuf_VHTOpra_t *tlv_vht_oper = NULL;
/* Check arguments */
if (argc != 4) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_setinfo <config/tdls.conf>\n");
exit(1);
}
cmd_len = sizeof(tdls_setinfo);
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate memory!\n");
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
param_buf = (tdls_setinfo *)buffer;
param_buf->action = ACTION_TDLS_SETINFO;
/* Check if file exists */
config_file = fopen(argv[3], "r");
if (config_file == NULL) {
printf("\nERR:Config file can not open.\n");
goto done;
}
line = (char *)malloc(MAX_CONFIG_LINE);
if (!line) {
printf("ERR:Cannot allocate memory for line\n");
goto done;
}
memset(line, 0, MAX_CONFIG_LINE);
/* Parse file and process */
while (config_get_line(line, MAX_CONFIG_LINE, config_file, &li, &pos)) {
arg_num = parse_line(line, args);
if (!cmd_found && strncmp(args[0], argv[2], strlen(args[0])))
continue;
cmd_found = 1;
if (strcmp(args[0], "CapInfo") == 0) {
param_buf->cap_info = (t_u16)A2HEXDECIMAL(args[1]);
param_buf->cap_info = cpu_to_le16(param_buf->cap_info);
} else if (strcmp(args[0], "Rate") == 0) {
tlvbuf_RatesParamSet_t *tlv = NULL;
/* Append a new TLV */
tlv_len = sizeof(tlvbuf_RatesParamSet_t) + arg_num - 1;
tlv = (tlvbuf_RatesParamSet_t *)(buffer + cmd_len);
cmd_len += tlv_len;
/* Set TLV fields */
tlv->tag = TLV_TYPE_RATES;
tlv->length = arg_num - 1;
for (i = 0; i < tlv->length; i++) {
tlv->rates[i] = (t_u8)A2HEXDECIMAL(args[i + 1]);
}
endian_convert_tlv_header_out(tlv);
} else if (strcmp(args[0], "QosInfo") == 0) {
tlvbuf_QosInfo_t *tlv = NULL;
/* Append a new TLV */
tlv_len = sizeof(tlvbuf_QosInfo_t);
tlv = (tlvbuf_QosInfo_t *)(buffer + cmd_len);
cmd_len += tlv_len;
/* Set TLV fields */
tlv->tag = TLV_TYPE_QOSINFO;
tlv->length = sizeof(tlvbuf_QosInfo_t) - TLVHEADER_LEN;
tlv->u.qos_info_byte = (t_u8)A2HEXDECIMAL(args[1]);
if ((tlv->u.qos_info_byte != 0) &&
(tlv->u.qos_info_byte != 0x0F)) {
printf("Invalid QosInfo. Should be 0x00 or 0x0F.\n");
goto done;
}
endian_convert_tlv_header_out(tlv);
} else if (strcmp(args[0], "ExtendCapabilities") == 0) {
tlvbuf_ExtCap_t *tlv = NULL;
/* Append a new TLV */
tlv_len = sizeof(tlvbuf_ExtCap_t) + arg_num - 1;
tlv = (tlvbuf_ExtCap_t *)(buffer + cmd_len);
cmd_len += tlv_len;
/* Set TLV fields */
tlv->tag = TLV_TYPE_EXTCAP;
tlv->length = arg_num - 1;
for (i = 0; i < tlv->length; i++) {
tlv->ext_cap[i] =
(t_u8)A2HEXDECIMAL(args[i + 1]);
}
endian_convert_tlv_header_out(tlv);
} else if (strcmp(args[0], "HTCapability") == 0) {
/* Append a new TLV */
tlv_ht_cap = (tlvbuf_HTCap_t *)(buffer + cmd_len);
tlv_len = sizeof(tlvbuf_HTCap_t);
tlv_ht_cap->tag = TLV_TYPE_HT_CAP;
tlv_ht_cap->length =
sizeof(tlvbuf_HTCap_t) - TLVHEADER_LEN;
cmd_len += tlv_len;
endian_convert_tlv_header_out(tlv_ht_cap);
} else if (strcmp(args[0], "HTCapabilityInfo") == 0) {
tlv_ht_cap->ht_cap.ht_cap_info =
(t_u16)A2HEXDECIMAL(args[1]);
tlv_ht_cap->ht_cap.ht_cap_info =
cpu_to_le16(tlv_ht_cap->ht_cap.ht_cap_info);
} else if (strcmp(args[0], "AMPDUParam") == 0) {
tlv_ht_cap->ht_cap.ampdu_param =
(t_u8)A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "SupportedMCSSet") == 0) {
for (i = 0; i < MCS_SET_LEN; i++)
tlv_ht_cap->ht_cap.supported_mcs_set[i] =
(t_u8)A2HEXDECIMAL(args[i + 1]);
} else if (strcmp(args[0], "HTExtCapability") == 0) {
tlv_ht_cap->ht_cap.ht_ext_cap =
(t_u16)A2HEXDECIMAL(args[1]);
tlv_ht_cap->ht_cap.ht_ext_cap =
cpu_to_le16(tlv_ht_cap->ht_cap.ht_ext_cap);
} else if (strcmp(args[0], "TxBfCapability") == 0) {
tlv_ht_cap->ht_cap.tx_bf_cap =
(t_u32)A2HEXDECIMAL(args[1]);
tlv_ht_cap->ht_cap.tx_bf_cap =
cpu_to_le32(tlv_ht_cap->ht_cap.tx_bf_cap);
} else if (strcmp(args[0], "AntennaSel") == 0) {
tlv_ht_cap->ht_cap.asel = (t_u8)A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "HTInformation") == 0) {
/* Append a new TLV */
tlv_ht_info = (tlvbuf_HTInfo_t *)(buffer + cmd_len);
tlv_len = sizeof(tlvbuf_HTInfo_t);
tlv_ht_info->tag = TLV_TYPE_HT_INFO;
tlv_ht_info->length =
sizeof(tlvbuf_HTInfo_t) - TLVHEADER_LEN;
cmd_len += tlv_len;
endian_convert_tlv_header_out(tlv_ht_info);
} else if (strcmp(args[0], "PrimaryChannel") == 0) {
tlv_ht_info->ht_info.pri_chan = A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "Field2") == 0) {
tlv_ht_info->ht_info.field2 = A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "Field3") == 0) {
tlv_ht_info->ht_info.field3 =
(t_u16)A2HEXDECIMAL(args[1]);
tlv_ht_info->ht_info.field3 =
cpu_to_le16(tlv_ht_info->ht_info.field3);
} else if (strcmp(args[0], "Field4") == 0) {
tlv_ht_info->ht_info.field4 =
(t_u16)A2HEXDECIMAL(args[1]);
tlv_ht_info->ht_info.field4 =
cpu_to_le16(tlv_ht_info->ht_info.field4);
} else if (strcmp(args[0], "BasicMCSSet") == 0) {
if ((arg_num - 1) != MCS_SET_LEN) {
printf("Incorrect number of arguments for BasicMCSSet.\n");
goto done;
}
for (i = 0; i < MCS_SET_LEN; i++)
tlv_ht_info->ht_info.basic_mcs_set[i] =
(t_u8)A2HEXDECIMAL(args[i + 1]);
} else if (strcmp(args[0], "2040BSSCoex") == 0) {
tlvbuf_2040BSSCo_t *tlv = NULL;
/* Append a new TLV */
tlv_len = sizeof(tlvbuf_2040BSSCo_t);
tlv = (tlvbuf_2040BSSCo_t *)(buffer + cmd_len);
cmd_len += tlv_len;
/* Set TLV fields */
tlv->tag = TLV_TYPE_2040BSS_COEXISTENCE;
tlv->length =
sizeof(tlvbuf_2040BSSCo_t) - TLVHEADER_LEN;
tlv->bss_co_2040.bss_co_2040_value =
(t_u8)A2HEXDECIMAL(args[1]);
endian_convert_tlv_header_out(tlv);
} else if (strcmp(args[0], "RSNInfo") == 0) {
/* Append a new TLV */
rsn_ie = (tlvbuf_RsnParamSet_t *)(buffer + cmd_len);
tlv_len_rsn = sizeof(tlvbuf_RsnParamSet_t);
rsn_ie->tag = TLV_TYPE_RSN_IE;
rsn_ie->version = VERSION_RSN_IE;
rsn_ie->version = cpu_to_le16(rsn_ie->version);
cmd_len += tlv_len_rsn;
} else if (strcmp(args[0], "GroupCipherSuite") == 0) {
for (i = 0; i < GROUP_CIPHER_SUITE_LEN; i++)
rsn_ie->group_cipher_suite[i] =
(t_u8)A2HEXDECIMAL(args[i + 1]);
} else if (strcmp(args[0], "PairwiseCipherCount") == 0) {
rsn_ie->pairwise_cipher_count = (t_u16)atoi(args[1]);
rsn_ie->pairwise_cipher_count =
cpu_to_le16(rsn_ie->pairwise_cipher_count);
} else if (strncmp(args[0], "PairwiseCipherSuite", 19) == 0) {
if (pairwise_index > MAX_PAIRWISE_CIPHER_SUITE_COUNT) {
printf("PairwiseCipherSuite exceeds max count\n");
goto done;
}
tlv_len_rsn += PAIRWISE_CIPHER_SUITE_LEN;
cmd_len += PAIRWISE_CIPHER_SUITE_LEN;
for (i = 0; i < PAIRWISE_CIPHER_SUITE_LEN; i++) {
pairwise_cipher_suite[i] =
(t_u8)A2HEXDECIMAL(args[i + 1]);
}
memcpy((t_u8 *)(rsn_ie->pairwise_cipher_suite +
(pairwise_index *
PAIRWISE_CIPHER_SUITE_LEN)),
pairwise_cipher_suite,
PAIRWISE_CIPHER_SUITE_LEN);
pairwise_index++;
pairwise_offset =
pairwise_index * PAIRWISE_CIPHER_SUITE_LEN;
} else if (strcmp(args[0], "AKMSuiteCount") == 0) {
akm_count = (t_u16)atoi(args[1]);
akm_count = cpu_to_le16(akm_count);
memcpy((((t_u8 *)(&rsn_ie->akm_suite_count)) +
pairwise_offset), &akm_count, sizeof(t_u16));
} else if (strncmp(args[0], "AKMSuite", 8) == 0) {
if (akm_index > MAX_AKM_SUITE_COUNT) {
printf("AKMSuite exceeds max count\n");
goto done;
}
tlv_len_rsn += AKM_SUITE_LEN;
cmd_len += AKM_SUITE_LEN;
for (i = 0; i < AKM_SUITE_LEN; i++) {
akm_suite[i] = (t_u8)A2HEXDECIMAL(args[i + 1]);
}
memcpy((t_u8 *)(rsn_ie->akm_suite +
(akm_index * AKM_SUITE_LEN)
+ pairwise_offset), akm_suite,
AKM_SUITE_LEN);
akm_index++;
akm_offset = akm_index * AKM_SUITE_LEN;
} else if (strcmp(args[0], "RSNCapability") == 0) {
rsn_cap = (t_u16)A2HEXDECIMAL(args[1]);
rsn_cap = cpu_to_le16(rsn_cap);
memcpy(((t_u8 *)(&(rsn_ie->rsn_capability))) +
pairwise_offset + akm_offset, &rsn_cap,
sizeof(t_u16));
} else if (strcmp(args[0], "PMKIDCount") == 0) {
pmk_count = (t_u16)atoi(args[1]);
pmk_count = cpu_to_le16(pmk_count);
memcpy((((t_u8 *)(&rsn_ie->pmkid_count)) +
pairwise_offset + akm_offset), &pmk_count,
sizeof(t_u16));
rsn_ie->length = tlv_len_rsn - TLVHEADER_LEN;
endian_convert_tlv_header_out(rsn_ie);
} else if (strncmp(args[0], "PMKIDList", 9) == 0) {
if (pmkid_index > MAX_PMKID_COUNT) {
printf("PMKIDSuite exceeds max count\n");
goto done;
}
for (i = 0; i < PMKID_LEN; i++)
pmkid[i] = (t_u8)A2HEXDECIMAL(args[i + 1]);
memcpy((t_u8 *)(rsn_ie->pmkid_list +
(pmkid_index * PMKID_LEN) +
pairwise_offset + akm_offset), pmkid,
PMKID_LEN);
pmkid_index++;
tlv_len_rsn += PMKID_LEN;
cmd_len += PMKID_LEN;
/* undo conversion done in PMKIDCount */
endian_convert_tlv_header_in(rsn_ie);
rsn_ie->length = tlv_len_rsn - TLVHEADER_LEN;
endian_convert_tlv_header_out(rsn_ie);
} else if (strcmp(args[0], "SupportedChannels") == 0) {
/* Append a new TLV */
supp_chan =
(tlvbuf_SupportedChannels_t *)(buffer +
cmd_len);
supp_chan->tag = TLV_TYPE_SUPPORTED_CHANNELS;
supp_chan->length = sizeof(tlvbuf_SupportedChannels_t)
- TLVHEADER_LEN;
tlv_len_supp_chan = sizeof(tlvbuf_SupportedChannels_t);
cmd_len += tlv_len_supp_chan;
} else if (strncmp(args[0], "FirstChannelNo", 14) == 0) {
supp_chan->subband[no_of_supp_chan_sub_band].
start_chan = atoi(args[1]);
} else if (strcmp(args[0], "NumberofSubBandChannels") == 0) {
supp_chan->subband[no_of_supp_chan_sub_band].num_chans =
atoi(args[1]);
no_of_supp_chan_sub_band++;
tlv_len_supp_chan +=
sizeof(IEEEtypes_SupportChan_Subband_t);
supp_chan->length +=
sizeof(IEEEtypes_SupportChan_Subband_t);
cmd_len += sizeof(IEEEtypes_SupportChan_Subband_t);
endian_convert_tlv_header_out(supp_chan);
} else if (strcmp(args[0], "SupportedRegulatoryClasses") == 0) {
/* Append a new TLV */
reg_class =
(tlvbuf_RegulatoryClass_t *)(buffer + cmd_len);
tlv_len_reg_class = sizeof(tlvbuf_RegulatoryClass_t);
reg_class->tag = TLV_TYPE_REGULATORY_CLASSES;
cmd_len += tlv_len_reg_class;
} else if (strcmp(args[0], "CurrentRegulatoryClass") == 0) {
reg_class->regulatory_class.cur_regulatory_class =
atoi(args[1]);
reg_class->length = 1;
} else if (strcmp(args[0], "NumofRegulatoryClasses") == 0) {
num_of_regulatory_class = atoi(args[1]);
reg_class->length += num_of_regulatory_class;
cmd_len += num_of_regulatory_class;
endian_convert_tlv_header_out(reg_class);
} else if (strcmp(args[0], "ListOfRegulatoryClasses") == 0) {
for (i = 0; i < num_of_regulatory_class; i++)
reg_class->regulatory_class.
regulatory_classes_list[i] =
(t_u8)A2HEXDECIMAL(args[i + 1]);
} else if (strcmp(args[0], "CountryInfo") == 0) {
/* Append a new TLV */
domain = (tlvbuf_DomainParamSet_t *)(buffer + cmd_len);
domain->tag = TLV_TYPE_DOMAIN;
domain->length = sizeof(tlvbuf_DomainParamSet_t)
- TLVHEADER_LEN;
tlv_len_domain = sizeof(tlvbuf_DomainParamSet_t);
cmd_len += tlv_len_domain;
} else if (strcmp(args[0], "CountryString") == 0) {
strncpy(country, args[1] + 1, strlen(args[1]) - 2);
country[strlen(args[1]) - 2] = '\0';
for (i = 1; (unsigned int)i < strlen(country) - 2; i++) {
if ((country[i] < 'A') || (country[i] > 'z')) {
printf("Invalid Country Code\n");
goto done;
}
if (country[i] > 'Z')
country[i] = country[i] - 'a' + 'A';
}
memset(domain->country_code, ' ',
sizeof(domain->country_code));
memcpy(domain->country_code, country, strlen(country));
} else if (strncmp(args[0], "FirstChannel", 12) == 0) {
domain->sub_band[no_of_sub_band].first_chan =
atoi(args[1]);
} else if (strncmp(args[0], "NumberofChannels", 16) == 0) {
domain->sub_band[no_of_sub_band].no_of_chan =
atoi(args[1]);
} else if (strncmp(args[0], "TxPower", 7) == 0) {
domain->sub_band[no_of_sub_band].max_tx_pwr =
atoi(args[1]);
no_of_sub_band++;
domain->length += sizeof(IEEEtypes_SubbandSet_t);
tlv_len_domain += sizeof(IEEEtypes_SubbandSet_t);
cmd_len += sizeof(IEEEtypes_SubbandSet_t);
endian_convert_tlv_header_out(domain);
} else if (strcmp(args[0], "VHTCapability") == 0) {
/* Append a new TLV */
tlv_vht_cap = (tlvbuf_VHTCap_t *)(buffer + cmd_len);
tlv_len = sizeof(tlvbuf_VHTCap_t);
tlv_vht_cap->tag = VHT_CAPABILITY;
tlv_vht_cap->length =
sizeof(tlvbuf_VHTCap_t) - TLVHEADER_LEN;
cmd_len += tlv_len;
endian_convert_tlv_header_out(tlv_vht_cap);
} else if (strcmp(args[0], "VHTCapabilityInfo") == 0) {
tlv_vht_cap->vht_cap.vht_cap_info =
(t_u32)A2HEXDECIMAL(args[1]);
tlv_vht_cap->vht_cap.vht_cap_info =
cpu_to_le16(tlv_vht_cap->vht_cap.vht_cap_info);
} else if (strcmp(args[0], "RxMCSMap") == 0) {
tlv_vht_cap->vht_cap.mcs_sets.rx_mcs_map =
(t_u16)A2HEXDECIMAL(args[1]);
tlv_vht_cap->vht_cap.mcs_sets.rx_mcs_map =
cpu_to_le16(tlv_vht_cap->vht_cap.mcs_sets.
rx_mcs_map);
} else if (strcmp(args[0], "TxMCSMap") == 0) {
tlv_vht_cap->vht_cap.mcs_sets.tx_mcs_map =
(t_u16)A2HEXDECIMAL(args[1]);
tlv_vht_cap->vht_cap.mcs_sets.tx_mcs_map =
cpu_to_le16(tlv_vht_cap->vht_cap.mcs_sets.
tx_mcs_map);
} else if (strcmp(args[0], "RxMaxRate") == 0) {
tlv_vht_cap->vht_cap.mcs_sets.rx_max_rate =
(t_u16)A2HEXDECIMAL(args[1]);
tlv_vht_cap->vht_cap.mcs_sets.rx_max_rate =
cpu_to_le16(tlv_vht_cap->vht_cap.mcs_sets.
rx_max_rate);
} else if (strcmp(args[0], "TxMaxRate") == 0) {
tlv_vht_cap->vht_cap.mcs_sets.tx_max_rate =
(t_u16)A2HEXDECIMAL(args[1]);
tlv_vht_cap->vht_cap.mcs_sets.tx_max_rate =
cpu_to_le16(tlv_vht_cap->vht_cap.mcs_sets.
tx_max_rate);
} else if (strcmp(args[0], "VHTOper") == 0) {
/* Append a new TLV */
tlv_vht_oper = (tlvbuf_VHTOpra_t *)(buffer + cmd_len);
tlv_len = sizeof(tlvbuf_VHTOpra_t);
tlv_vht_oper->tag = VHT_OPERATION;
tlv_vht_oper->length =
sizeof(tlvbuf_VHTOpra_t) - TLVHEADER_LEN;
cmd_len += tlv_len;
endian_convert_tlv_header_out(tlv_vht_oper);
} else if (strcmp(args[0], "ChanWidth") == 0) {
tlv_vht_oper->chan_width = A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "ChanCF1") == 0) {
tlv_vht_oper->chan_cf1 = A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "ChanCF2") == 0) {
tlv_vht_oper->chan_cf2 = (t_u16)A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "BasicMCSMap") == 0) {
if ((arg_num - 1) != VHT_MCS_MAP_LEN) {
printf("Incorrect number of arguments for BasicMCSMap.\n");
goto done;
}
for (i = 0; i < VHT_MCS_MAP_LEN; i++)
tlv_vht_oper->basic_mcs_map[i] =
(t_u8)A2HEXDECIMAL(args[i + 1]);
}
}
/* adjust for size of action and tlv_len, capInfo */
param_buf->tlv_len = cmd_len - sizeof(tdls_setinfo);
hexdump("tdls_setinfo", buffer, cmd_len, ' ');
/* Send collective command */
ret = tdls_ioctl((t_u8 *)buffer, cmd_len);
/* Process response */
if (ret == MLAN_STATUS_SUCCESS) {
printf("TDLS Info settings sucessfully set.\n");
} else {
printf("ERR:Could not set TDLS info configuration.\n");
}
done:
if (config_file)
fclose(config_file);
if (buffer)
free(buffer);
if (line)
free(line);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process tdls_discovery
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_tdls_discovery(int argc, char *argv[])
{
tdls_discovery *param_buf = NULL;
tdls_discovery_resp *resp_buf = NULL;
char *line = NULL;
FILE *config_file = NULL;
int li = 0, ret = 0, cmd_found = 0, rssi = 0;
char *args[30], *pos = NULL, mac_addr[20];
t_u8 peer_mac[ETH_ALEN];
t_u16 cmd_len = 0, buf_len = 0, resp_len = 0;
t_u8 *buffer = NULL, *raw = NULL;
IEEEtypes_Header_t *tlv = NULL;
/* Check arguments */
if (argc != 4) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_discovery <config/tdls.conf>\n");
exit(1);
}
cmd_len = sizeof(tdls_discovery);
buf_len = BUFFER_LENGTH;
buffer = (t_u8 *)malloc(buf_len);
if (!buffer) {
printf("ERR:Cannot allocate memory!\n");
goto done;
}
memset(buffer, 0, buf_len);
param_buf = (tdls_discovery *)buffer;
param_buf->action = ACTION_TDLS_DISCOVERY;
/* Check if file exists */
config_file = fopen(argv[3], "r");
if (config_file == NULL) {
printf("\nERR:Config file can not open.\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
line = (char *)malloc(MAX_CONFIG_LINE);
if (!line) {
printf("ERR:Cannot allocate memory for line\n");
goto done;
}
memset(line, 0, MAX_CONFIG_LINE);
/* Parse file and process */
while (config_get_line(line, MAX_CONFIG_LINE, config_file, &li, &pos)) {
parse_line(line, args);
if (!cmd_found && strncmp(args[0], argv[2], strlen(args[0])))
continue;
cmd_found = 1;
if (strcmp(args[0], "PeerMAC") == 0) {
strncpy(mac_addr, args[1], 20);
ret = mac2raw(mac_addr, peer_mac);
if (ret != MLAN_STATUS_SUCCESS) {
printf("ERR: %s Address \n",
ret ==
MLAN_STATUS_FAILURE ? "Invalid MAC" : ret
==
MAC_BROADCAST ? "Broadcast" :
"Multicast");
goto done;
}
memcpy(param_buf->peer_mac, peer_mac, ETH_ALEN);
} else if (strcmp(args[0], "}") == 0 && cmd_found) {
break;
}
}
hexdump("tdls_discovery", buffer, cmd_len, ' ');
/* Send collective command */
ret = tdls_ioctl((t_u8 *)buffer, cmd_len);
/* Process response */
if (ret == MLAN_STATUS_SUCCESS) {
hexdump("tdls_response", buffer, 0x40, ' ');
printf("TDLS discovery done.\n");
resp_buf = (tdls_discovery_resp *)buffer;
resp_len = resp_buf->payload_len;
printf("Response Length = %d\n", resp_len);
if (resp_len > 0) {
/* MAC */
raw = resp_buf->peer_mac;
printf("\tPeer - %02x:%02x:%02x:%02x:%02x:%02x\n",
(unsigned int)raw[0], (unsigned int)raw[1],
(unsigned int)raw[2], (unsigned int)raw[3],
(unsigned int)raw[4], (unsigned int)raw[5]);
/* RSSI, CapInfo */
rssi = (int)(resp_buf->rssi);
if (rssi > 0x7f)
rssi = -(256 - rssi);
printf("\tRssi : %d dBm\n", rssi);
printf("\tCapInfo = 0x%02X\n", resp_buf->cap_info);
resp_len -= ETH_ALEN + sizeof(resp_buf->rssi) +
sizeof(resp_buf->cap_info);
/* TLVs */
tlv = (IEEEtypes_Header_t *)&resp_buf->tlv_buffer;
while (resp_len > IEEE_HEADER_LEN) {
switch (tlv->element_id) {
case TLV_TYPE_RATES:
printf("\tRates : ");
hexdump(NULL,
((t_u8 *)tlv) + IEEE_HEADER_LEN,
tlv->len, ' ');
break;
case TLV_EXTENDED_SUPPORTED_RATES:
printf("\tExtended Rates : ");
hexdump(NULL,
((t_u8 *)tlv) + IEEE_HEADER_LEN,
tlv->len, ' ');
break;
case TLV_TYPE_QOSINFO:
printf("\tQosInfo ");
hexdump(NULL,
((t_u8 *)tlv) + IEEE_HEADER_LEN,
tlv->len, ' ');
break;
case TLV_TYPE_EXTCAP:
printf("\tExtended Cap ");
hexdump(NULL,
((t_u8 *)tlv) + IEEE_HEADER_LEN,
tlv->len, ' ');
break;
case TLV_TYPE_HT_CAP:
printf("\tHT Cap ");
hexdump(NULL,
((t_u8 *)tlv) + IEEE_HEADER_LEN,
tlv->len, ' ');
break;
case TLV_TYPE_HT_INFO:
printf("\tHT Info");
hexdump(NULL,
((t_u8 *)tlv) + IEEE_HEADER_LEN,
tlv->len, ' ');
break;
case TLV_TYPE_2040BSS_COEXISTENCE:
printf("\t2040 BSS Coex ");
hexdump(NULL,
((t_u8 *)tlv) + IEEE_HEADER_LEN,
tlv->len, ' ');
break;
case TLV_TYPE_RSN_IE:
printf("\tRSN IE ");
hexdump(NULL,
((t_u8 *)tlv) + IEEE_HEADER_LEN,
tlv->len, ' ');
break;
case TLV_TYPE_SUPPORTED_CHANNELS:
printf("\tSupported Channels ");
hexdump(NULL,
((t_u8 *)tlv) + IEEE_HEADER_LEN,
tlv->len, ' ');
break;
case TLV_TYPE_DOMAIN:
printf("\tDomain Info ");
hexdump(NULL,
((t_u8 *)tlv) + IEEE_HEADER_LEN,
tlv->len, ' ');
break;
case TLV_LINK_IDENTIFIER:
printf("\tLink identifier : ");
hexdump(NULL,
((t_u8 *)tlv) + IEEE_HEADER_LEN,
tlv->len, ' ');
break;
case TLV_TIMEOUT_INTERVAL:
printf("\tTimeout interval : ");
hexdump(NULL,
((t_u8 *)tlv) + IEEE_HEADER_LEN,
tlv->len, ' ');
break;
case TLV_TYPE_REGULATORY_CLASSES:
printf("\t Regulatory classes : ");
hexdump(NULL,
((t_u8 *)tlv) + IEEE_HEADER_LEN,
tlv->len, ' ');
break;
default:
printf("Unknown TLV\n");
hexdump(NULL, ((t_u8 *)tlv),
IEEE_HEADER_LEN + tlv->len,
' ');
break;
}
resp_len -= tlv->len + IEEE_HEADER_LEN;
tlv = (IEEEtypes_Header_t *)((t_u8 *)tlv +
tlv->len +
IEEE_HEADER_LEN);
}
}
} else {
printf("ERR:Command response = Fail!\n");
}
done:
if (config_file)
fclose(config_file);
if (buffer)
free(buffer);
if (line)
free(line);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process tdls_setup
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_tdls_setup(int argc, char *argv[])
{
tdls_setup *param_buf = NULL;
char *line = NULL;
FILE *config_file = NULL;
int li = 0, ret = 0, cmd_found = 0;
char *args[30], *pos = NULL, mac_addr[20];
t_u8 peer_mac[ETH_ALEN];
t_u16 cmd_len = 0;
t_u8 *buffer = NULL;
/* Check arguments */
if (argc != 4) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_setup <config/tdls.conf>\n");
exit(1);
}
cmd_len = sizeof(tdls_setup);
buffer = (t_u8 *)malloc(cmd_len);
if (!buffer) {
printf("ERR:Cannot allocate memory!\n");
goto done;
}
memset(buffer, 0, cmd_len);
param_buf = (tdls_setup *) buffer;
param_buf->action = ACTION_TDLS_SETUP;
/* Check if file exists */
config_file = fopen(argv[3], "r");
if (config_file == NULL) {
printf("\nERR:Config file can not open.\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
line = (char *)malloc(MAX_CONFIG_LINE);
if (!line) {
printf("ERR:Cannot allocate memory for line\n");
goto done;
}
memset(line, 0, MAX_CONFIG_LINE);
/* Parse file and process */
while (config_get_line(line, MAX_CONFIG_LINE, config_file, &li, &pos)) {
parse_line(line, args);
if (!cmd_found && strncmp(args[0], argv[2], strlen(args[0])))
continue;
cmd_found = 1;
if (strcmp(args[0], "PeerMAC") == 0) {
strncpy(mac_addr, args[1], 20);
ret = mac2raw(mac_addr, peer_mac);
if (ret != MLAN_STATUS_SUCCESS) {
printf("ERR: %s Address \n",
ret ==
MLAN_STATUS_FAILURE ? "Invalid MAC" : ret
==
MAC_BROADCAST ? "Broadcast" :
"Multicast");
goto done;
}
memcpy(param_buf->peer_mac, peer_mac, ETH_ALEN);
} else if (strcmp(args[0], "WaitTimems") == 0) {
param_buf->wait_time = (t_u32)A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "KeyLifetime") == 0) {
param_buf->key_life_time = (t_u32)A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "}") == 0 && cmd_found) {
break;
}
}
hexdump("tdls_setup", buffer, cmd_len, ' ');
/* Send collective command */
ret = tdls_ioctl((t_u8 *)buffer, cmd_len);
/* Process response */
if (ret == MLAN_STATUS_SUCCESS) {
printf("TDLS setup request successful.\n");
} else {
printf("ERR:TDLS setup request failed.\n");
}
done:
if (config_file)
fclose(config_file);
if (buffer)
free(buffer);
if (line)
free(line);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process tdls_teardown
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_tdls_teardown(int argc, char *argv[])
{
tdls_teardown *param_buf = NULL;
char *line = NULL;
FILE *config_file = NULL;
int li = 0, ret = 0, cmd_found = 0;
char *args[30], *pos = NULL, mac_addr[20];
t_u8 peer_mac[ETH_ALEN];
t_u16 cmd_len = 0;
t_u8 *buffer = NULL;
/* Check arguments */
if (argc != 4) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_teardown <config/tdls.conf>\n");
exit(1);
}
cmd_len = sizeof(tdls_teardown);
buffer = (t_u8 *)malloc(cmd_len);
if (!buffer) {
printf("ERR:Cannot allocate memory!\n");
goto done;
}
memset(buffer, 0, cmd_len);
param_buf = (tdls_teardown *)buffer;
param_buf->action = ACTION_TDLS_TEARDOWN;
/* Check if file exists */
config_file = fopen(argv[3], "r");
if (config_file == NULL) {
printf("\nERR:Config file can not open.\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
line = (char *)malloc(MAX_CONFIG_LINE);
if (!line) {
printf("ERR:Cannot allocate memory for line\n");
goto done;
}
memset(line, 0, MAX_CONFIG_LINE);
/* Parse file and process */
while (config_get_line(line, MAX_CONFIG_LINE, config_file, &li, &pos)) {
parse_line(line, args);
if (!cmd_found && strncmp(args[0], argv[2], strlen(args[0])))
continue;
cmd_found = 1;
if (strcmp(args[0], "PeerMAC") == 0) {
strncpy(mac_addr, args[1], 20);
ret = mac2raw(mac_addr, peer_mac);
if (ret != MLAN_STATUS_SUCCESS) {
printf("ERR: %s Address \n",
ret ==
MLAN_STATUS_FAILURE ? "Invalid MAC" : ret
==
MAC_BROADCAST ? "Broadcast" :
"Multicast");
goto done;
}
memcpy(param_buf->peer_mac, peer_mac, ETH_ALEN);
} else if (strcmp(args[0], "ReasonCode") == 0) {
param_buf->reason_code = (t_u16)A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "}") == 0 && cmd_found) {
break;
}
}
hexdump("tdls_teardown", buffer, cmd_len, ' ');
/* Send collective command */
ret = tdls_ioctl((t_u8 *)buffer, cmd_len);
/* Process response */
if (ret == MLAN_STATUS_SUCCESS) {
printf("TDLS teardown request successful.\n");
} else {
printf("ERR:TDLS teardown request failed.\n");
}
done:
if (config_file)
fclose(config_file);
if (buffer)
free(buffer);
if (line)
free(line);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process tdls_powermode
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_tdls_powermode(int argc, char *argv[])
{
tdls_powermode *param_buf = NULL;
char *line = NULL;
FILE *config_file = NULL;
int li = 0, ret = 0, cmd_found = 0;
char *args[30], *pos = NULL, mac_addr[20];
t_u8 peer_mac[ETH_ALEN];
t_u16 cmd_len = 0;
t_u8 *buffer = NULL;
/* Check arguments */
if (argc != 4) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_powermode <config/tdls.conf>\n");
exit(1);
}
cmd_len = sizeof(tdls_powermode);
buffer = (t_u8 *)malloc(cmd_len);
if (!buffer) {
printf("ERR:Cannot allocate memory!\n");
goto done;
}
memset(buffer, 0, cmd_len);
param_buf = (tdls_powermode *)buffer;
param_buf->action = ACTION_TDLS_POWER_MODE;
/* Check if file exists */
config_file = fopen(argv[3], "r");
if (config_file == NULL) {
printf("\nERR:Config file can not open.\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
line = (char *)malloc(MAX_CONFIG_LINE);
if (!line) {
printf("ERR:Cannot allocate memory for line\n");
goto done;
}
memset(line, 0, MAX_CONFIG_LINE);
/* Parse file and process */
while (config_get_line(line, MAX_CONFIG_LINE, config_file, &li, &pos)) {
parse_line(line, args);
if (!cmd_found && strncmp(args[0], argv[2], strlen(args[0])))
continue;
cmd_found = 1;
if (strcmp(args[0], "PeerMAC") == 0) {
strncpy(mac_addr, args[1], 20);
ret = mac2raw(mac_addr, peer_mac);
if (ret != MLAN_STATUS_SUCCESS) {
printf("ERR: %s Address \n",
ret ==
MLAN_STATUS_FAILURE ? "Invalid MAC" : ret
==
MAC_BROADCAST ? "Broadcast" :
"Multicast");
goto done;
}
memcpy(param_buf->peer_mac, peer_mac, ETH_ALEN);
} else if (strcmp(args[0], "PowerMode") == 0) {
param_buf->power_mode = (t_u16)A2HEXDECIMAL(args[1]);
if (param_buf->power_mode > 1) {
printf("ERR: Incorrect PowerMode value %s\n",
args[1]);
goto done;
}
} else if (strcmp(args[0], "}") == 0 && cmd_found) {
break;
}
}
hexdump("tdls_powermode", buffer, cmd_len, ' ');
/* Send collective command */
ret = tdls_ioctl((t_u8 *)buffer, cmd_len);
/* Process response */
if (ret == MLAN_STATUS_SUCCESS) {
printf("TDLS powermode request successful.\n");
} else {
printf("ERR:TDLS powermode request failed.\n");
}
done:
if (config_file)
fclose(config_file);
if (buffer)
free(buffer);
if (line)
free(line);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process tdls_link_status
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_tdls_link_status(int argc, char *argv[])
{
int ret = 0;
tdls_link_status *param_buf = NULL;
tdls_link_status_resp *resp_buf = NULL;
t_u16 cmd_len = 0, buf_len = 0, resp_len = 0, curr_link_len = 0;
t_u8 no_of_links = 0, peer_mac[ETH_ALEN];
t_u8 *buffer = NULL, *raw = NULL;
tdls_each_link_status *link_ptr = NULL;
/* Check arguments */
if (argc != 3 && argc != 4) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_link_status [peer_mac_addr]\n");
exit(1);
}
cmd_len = sizeof(tdls_link_status);
buf_len = BUFFER_LENGTH;
buffer = (t_u8 *)malloc(buf_len);
if (!buffer) {
printf("ERR:Cannot allocate memory!\n");
goto done;
}
memset(buffer, 0, buf_len);
param_buf = (tdls_link_status *)buffer;
param_buf->action = ACTION_TDLS_LINK_STATUS;
if (argc == 4) {
ret = mac2raw(argv[3], peer_mac);
if (ret != MLAN_STATUS_SUCCESS) {
printf("ERR: %s Address \n",
ret ==
MLAN_STATUS_FAILURE ? "Invalid MAC" : ret ==
MAC_BROADCAST ? "Broadcast" : "Multicast");
goto done;
}
if (memcmp(peer_mac, "\x00\x00\x00\x00\x00\x00", ETH_ALEN)) {
memcpy(buffer + cmd_len, peer_mac, ETH_ALEN);
cmd_len += ETH_ALEN;
}
}
/* Send collective command */
ret = tdls_ioctl((t_u8 *)buffer, cmd_len);
/* Process response */
if (ret == MLAN_STATUS_SUCCESS) {
hexdump("tdls_response", buffer, 0x60, ' ');
printf("TDLS Link Status - .\n");
resp_buf = (tdls_link_status_resp *)buffer;
resp_len = resp_buf->payload_len;
printf("Response Length = %d\n", resp_len);
no_of_links = resp_buf->active_links;
printf("No of active links = %d\n", no_of_links);
resp_len--;
link_ptr = resp_buf->link_stats;
while (resp_len > 0 && no_of_links > 0) {
curr_link_len = 0;
/* MAC */
raw = link_ptr->peer_mac;
printf("\tPeer - %02x:%02x:%02x:%02x:%02x:%02x\n",
(unsigned int)raw[0], (unsigned int)raw[1],
(unsigned int)raw[2], (unsigned int)raw[3],
(unsigned int)raw[4], (unsigned int)raw[5]);
printf("\t %s initiated link.\n",
(link_ptr->link_flags & 0x01) ? "Self" : "Peer");
printf("\t Security %s.\n",
(link_ptr->
link_flags & 0x02) ? "Enabled" : "Disabled");
printf("\t Self PS status = %s.\n",
(link_ptr->
link_flags & 0x04) ? "Sleep" : "Active");
printf("\t Peer PS status = %s.\n",
(link_ptr->
link_flags & 0x08) ? "Sleep" : "Active");
printf("\t Channel switch is %ssupported\n",
(link_ptr->link_flags & 0x10) ? "" : "NOT ");
printf("\t Current Channel %s\n",
(link_ptr->link_flags & 0x20) ? "off" : "base");
if (link_ptr->traffic_status) {
printf("\t Buffered traffic for");
printf("%s",
(link_ptr->
traffic_status & 0x01) ? "AC_BK, " :
"");
printf("%s",
(link_ptr->
traffic_status & 0x02) ? "AC_BE, " :
"");
printf("%s",
(link_ptr->
traffic_status & 0x04) ? "AC_VI, " :
"");
printf("%s",
(link_ptr->
traffic_status & 0x08) ? "AC_VO" : "");
printf(".\n");
}
printf("\t Successive Tx Failure count = %d\n",
link_ptr->tx_fail_count);
printf("\t Active channel number = %d\n",
link_ptr->active_channel);
printf("\t Last Data RSSI = %d dBm\n",
link_ptr->data_rssi_last);
printf("\t Last Data NF = %d dBm\n",
link_ptr->data_nf_last);
printf("\t Average Data RSSI = %d dBm\n",
link_ptr->data_rssi_avg);
printf("\t Average Data NF = %d dBm\n",
link_ptr->data_nf_avg);
printf("\t Tx data rate = %d Mbps\n",
link_ptr->u.final_data_rate);
/* size of unsecure structure */
curr_link_len = sizeof(tdls_each_link_status) -
(sizeof(t_u32) + sizeof(t_u8) + sizeof(t_u8));
if (link_ptr->link_flags & 0x02) {
/* security details */
printf("\t Security Method = %s\n",
(link_ptr->security_method ==
1) ? "AES" : "None");
printf("\t Key Lifetime = %d ms\n\t",
link_ptr->key_lifetime);
hexdump("Key", ((t_u8 *)link_ptr->key),
link_ptr->key_length, ' ');
curr_link_len +=
sizeof(t_u32) + sizeof(t_u8) +
sizeof(t_u8)
+ link_ptr->key_length;
}
resp_len -= curr_link_len;
link_ptr =
(tdls_each_link_status *)(((t_u8 *)link_ptr) +
curr_link_len);
printf(".\n");
}
} else {
printf("ERR:Command response = Fail!\n");
}
done:
if (buffer)
free(buffer);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process tdls_channel_swtich
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_tdls_channel_switch(int argc, char *argv[])
{
tdls_channel_switch *param_buf = NULL;
char *line = NULL;
FILE *config_file = NULL;
int li = 0, ret = 0, cmd_found = 0;
char *args[30], *pos = NULL, mac_addr[20];
t_u8 peer_mac[ETH_ALEN];
t_u16 cmd_len = 0;
t_u8 *buffer = NULL;
/* Check arguments */
if (argc != 4) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_channel_switch <config/tdls.conf>\n");
exit(1);
}
cmd_len = sizeof(tdls_channel_switch);
buffer = (t_u8 *)malloc(cmd_len);
if (!buffer) {
printf("ERR:Cannot allocate memory!\n");
goto done;
}
memset(buffer, 0, cmd_len);
param_buf = (tdls_channel_switch *)buffer;
param_buf->action = ACTION_TDLS_INIT_CHAN_SWITCH;
/* Check if file exists */
config_file = fopen(argv[3], "r");
if (config_file == NULL) {
printf("\nERR:Config file can not open.\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
line = (char *)malloc(MAX_CONFIG_LINE);
if (!line) {
printf("ERR:Cannot allocate memory for line\n");
goto done;
}
memset(line, 0, MAX_CONFIG_LINE);
/* Parse file and process */
while (config_get_line(line, MAX_CONFIG_LINE, config_file, &li, &pos)) {
parse_line(line, args);
if (!cmd_found && strncmp(args[0], argv[2], strlen(args[0])))
continue;
cmd_found = 1;
if (strcmp(args[0], "PeerMAC") == 0) {
strncpy(mac_addr, args[1], 20);
ret = mac2raw(mac_addr, peer_mac);
if (ret != MLAN_STATUS_SUCCESS) {
printf("ERR: %s Address \n",
ret ==
MLAN_STATUS_FAILURE ? "Invalid MAC" : ret
==
MAC_BROADCAST ? "Broadcast" :
"Multicast");
goto done;
}
memcpy(param_buf->peer_mac, peer_mac, ETH_ALEN);
} else if (strcmp(args[0], "Band") == 0) {
param_buf->band = (t_u16)A2HEXDECIMAL(args[1]);
if (param_buf->band != BAND_BG_TDLS &&
param_buf->band != BAND_A_TDLS) {
printf("ERR: Incorrect Band value %s\n",
args[1]);
goto done;
}
} else if (strcmp(args[0], "RegulatoryClass") == 0) {
param_buf->regulatory_class =
(t_u16)A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "PrimaryChannel") == 0) {
param_buf->primary_channel =
(t_u16)A2HEXDECIMAL(args[1]);
if (param_buf->band == BAND_BG_TDLS &&
param_buf->primary_channel < MIN_BG_CHANNEL &&
param_buf->primary_channel > MAX_BG_CHANNEL) {
printf("ERR: Incorrect Primary Channel value %s\n", args[1]);
goto done;
} else if (param_buf->band == BAND_A_TDLS
&& param_buf->primary_channel < MIN_A_CHANNEL
&& param_buf->primary_channel >
MAX_A_CHANNEL) {
printf("ERR: Incorrect Primary Channel value %s\n", args[1]);
goto done;
}
} else if (strcmp(args[0], "SecondaryChannelOffset") == 0) {
param_buf->secondary_channel_offset =
(t_u16)A2HEXDECIMAL(args[1]);
if (param_buf->secondary_channel_offset != SEC_CHAN_NONE
&& param_buf->secondary_channel_offset !=
SEC_CHAN_ABOVE &&
param_buf->secondary_channel_offset !=
SEC_CHAN_BELOW) {
printf("ERR: Incorrect Secondary Channel Offset value %s\n", args[1]);
goto done;
}
} else if (strcmp(args[0], "ChannelSwitchTime") == 0) {
param_buf->switch_time = (t_u16)A2HEXDECIMAL(args[1]);
if (param_buf->switch_time == 0) {
printf("ERR: Incorrect Channel Switch time %s\n", args[1]);
goto done;
}
} else if (strcmp(args[0], "ChannelSwitchTimeout") == 0) {
param_buf->switch_timeout =
(t_u16)A2HEXDECIMAL(args[1]);
if (param_buf->switch_timeout == 0) {
printf("ERR: Incorrect Channel Switch timeout %s\n", args[1]);
goto done;
}
} else if (strcmp(args[0], "Periodicity") == 0) {
param_buf->periodicity = (t_u16)A2HEXDECIMAL(args[1]);
if (param_buf->periodicity != NO_PERIODIC_SWITCH
&& param_buf->periodicity !=
ENABLE_PERIODIC_SWITCH) {
printf("ERR: Incorrect Periodicity value %s\n",
args[1]);
goto done;
}
} else if (strcmp(args[0], "}") == 0 && cmd_found) {
break;
}
}
hexdump("tdls_channel_switch", buffer, cmd_len, ' ');
/* Send collective command */
ret = tdls_ioctl((t_u8 *)buffer, cmd_len);
/* Process response */
if (ret == MLAN_STATUS_SUCCESS) {
printf("TDLS channel switch request successful.\n");
} else {
printf("ERR:TDLS channel switch request failed.\n");
}
done:
if (config_file)
fclose(config_file);
if (buffer)
free(buffer);
if (line)
free(line);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief disable tdls_channel_swtich
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_tdls_disable_channel_switch(int argc, char *argv[])
{
tdls_disable_cs *param_buf = NULL;
int ret = 0;
t_u16 cmd_len = 0;
t_u8 *buffer = NULL;
/* Check arguments */
if (argc != 4) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_disable_cs <0/1>\n");
exit(1);
}
cmd_len = sizeof(tdls_disable_cs);
buffer = (t_u8 *)malloc(cmd_len);
if (!buffer) {
printf("ERR:Cannot allocate memory!\n");
goto done;
}
memset(buffer, 0, cmd_len);
param_buf = (tdls_disable_cs *) buffer;
param_buf->action = ACTION_TDLS_CS_DISABLE;
param_buf->data = (t_u16)A2HEXDECIMAL(argv[3]);
if ((param_buf->data != 0) && (param_buf->data != 1)) {
printf("ERR:Incorrect arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_disable_cs <0/1>\n");
goto done;
}
hexdump("tdls_disable_cs", buffer, cmd_len, ' ');
/* Send collective command */
ret = tdls_ioctl((t_u8 *)buffer, cmd_len);
/* Process response */
if (ret == MLAN_STATUS_SUCCESS) {
printf("TDLS disable channel switch successful.\n");
} else {
printf("ERR:TDLS disable channel switch failed.\n");
}
done:
if (buffer)
free(buffer);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process tdls_stop_channel_switch
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_tdls_stop_channel_switch(int argc, char *argv[])
{
tdls_stop_chan_switch *param_buf = NULL;
char *line = NULL;
FILE *config_file = NULL;
int li = 0, ret = 0, cmd_found = 0;
char *args[30], *pos = NULL, mac_addr[20];
t_u8 peer_mac[ETH_ALEN];
t_u16 cmd_len = 0;
t_u8 *buffer = NULL;
/* Check arguments */
if (argc != 4) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_stop_channel_switch <config/tdls.conf>\n");
exit(1);
}
cmd_len = sizeof(tdls_stop_chan_switch);
buffer = (t_u8 *)malloc(cmd_len);
if (!buffer) {
printf("ERR:Cannot allocate memory!\n");
goto done;
}
memset(buffer, 0, cmd_len);
param_buf = (tdls_stop_chan_switch *) buffer;
param_buf->action = ACTION_TDLS_STOP_CHAN_SWITCH;
/* Check if file exists */
config_file = fopen(argv[3], "r");
if (config_file == NULL) {
printf("\nERR:Config file can not open.\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
line = (char *)malloc(MAX_CONFIG_LINE);
if (!line) {
printf("ERR:Cannot allocate memory for line\n");
goto done;
}
memset(line, 0, MAX_CONFIG_LINE);
/* Parse file and process */
while (config_get_line(line, MAX_CONFIG_LINE, config_file, &li, &pos)) {
parse_line(line, args);
if (!cmd_found && strncmp(args[0], argv[2], strlen(args[0])))
continue;
cmd_found = 1;
if (strcmp(args[0], "PeerMAC") == 0) {
strncpy(mac_addr, args[1], 20);
ret = mac2raw(mac_addr, peer_mac);
if (ret != MLAN_STATUS_SUCCESS) {
printf("ERR: %s Address \n",
ret ==
MLAN_STATUS_FAILURE ? "Invalid MAC" : ret
==
MAC_BROADCAST ? "Broadcast" :
"Multicast");
goto done;
}
memcpy(param_buf->peer_mac, peer_mac, ETH_ALEN);
} else if (strcmp(args[0], "}") == 0 && cmd_found) {
break;
}
}
hexdump("tdls_stop_channel_switch", buffer, cmd_len, ' ');
/* Send collective command */
ret = tdls_ioctl((t_u8 *)buffer, cmd_len);
/* Process response */
if (ret == MLAN_STATUS_SUCCESS) {
printf("TDLS stop channel switch successful.\n");
} else {
printf("ERR:TDLS stop channel switch failed.\n");
}
done:
if (config_file)
fclose(config_file);
if (buffer)
free(buffer);
if (line)
free(line);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process tdls_cs_params
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_tdls_cs_params(int argc, char *argv[])
{
tdls_cs_params *param_buf = NULL;
char *line = NULL;
FILE *config_file = NULL;
int li = 0, ret = 0, cmd_found = 0;
char *args[30], *pos = NULL;
t_u16 cmd_len = 0;
t_u8 *buffer = NULL;
/* Check arguments */
if (argc != 4) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_cs_params <config/tdls.conf>\n");
exit(1);
}
cmd_len = sizeof(tdls_cs_params);
buffer = (t_u8 *)malloc(cmd_len);
if (!buffer) {
printf("ERR:Cannot allocate memory!\n");
goto done;
}
memset(buffer, 0, cmd_len);
param_buf = (tdls_cs_params *) buffer;
param_buf->action = ACTION_TDLS_CS_PARAMS;
/* Check if file exists */
config_file = fopen(argv[3], "r");
if (config_file == NULL) {
printf("\nERR:Config file can not open.\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
line = (char *)malloc(MAX_CONFIG_LINE);
if (!line) {
printf("ERR:Cannot allocate memory for line\n");
goto done;
}
memset(line, 0, MAX_CONFIG_LINE);
/* Parse file and process */
while (config_get_line(line, MAX_CONFIG_LINE, config_file, &li, &pos)) {
parse_line(line, args);
if (!cmd_found && strncmp(args[0], argv[2], strlen(args[0])))
continue;
cmd_found = 1;
if (strcmp(args[0], "UnitTime") == 0) {
param_buf->unit_time = (t_u8)A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "ThresholdOtherLink") == 0) {
param_buf->threshold_otherlink =
(t_u8)A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "ThresholdDirectLink") == 0) {
param_buf->threshold_directlink =
(t_u8)A2HEXDECIMAL(args[1]);
} else if (strcmp(args[0], "}") == 0 && cmd_found) {
break;
}
}
hexdump("tdls_cs_params", buffer, cmd_len, ' ');
/* Send collective command */
ret = tdls_ioctl((t_u8 *)buffer, cmd_len);
/* Process response */
if (ret == MLAN_STATUS_SUCCESS) {
printf("TDLS set channel switch parameters successful.\n");
} else {
printf("ERR:TDLS set channel switch parameters failed.\n");
}
done:
if (config_file)
fclose(config_file);
if (buffer)
free(buffer);
if (line)
free(line);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process tdls_debug
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_tdls_debug(int argc, char *argv[])
{
int ret = 0;
tdls_debug *param_buf = NULL;
t_u16 cmd_len = 0;
t_u8 *buffer = NULL;
t_u16 action = 0, value = 0;
/* Check arguments */
if (argc < 4) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_debug <options>\n");
exit(1);
}
cmd_len = sizeof(tdls_debug);
/* wrong_bss */
if (!strcmp(argv[3], "wrong_bss")) {
cmd_len += sizeof(t_u16);
action = ACTION_TDLS_DEBUG_WRONG_BSS;
if (argc < 5) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_debug wrong_bss <0/1>\n");
exit(1);
}
value = (t_u16)A2HEXDECIMAL(argv[4]);
}
/* same link */
else if (!strcmp(argv[3], "setup_existing_link")) {
cmd_len += sizeof(t_u16);
action = ACTION_TDLS_DEBUG_SETUP_SAME_LINK;
if (argc < 5) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_debug setup_existing_link <0/1>\n");
exit(1);
}
value = (t_u16)A2HEXDECIMAL(argv[4]);
}
/* fail_setup_confirm */
else if (!strcmp(argv[3], "fail_setup_confirm")) {
cmd_len += sizeof(t_u16);
action = ACTION_TDLS_DEBUG_FAIL_SETUP_CONFIRM;
if (argc < 5) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_debug fail_setup_confirm <0/1>\n");
exit(1);
}
value = (t_u16)A2HEXDECIMAL(argv[4]);
}
/* setup prohibited */
else if (!strcmp(argv[3], "setup_with_prohibited")) {
cmd_len += sizeof(t_u16);
action = ACTION_TDLS_DEBUG_SETUP_PROHIBITED;
if (argc < 5) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_debug setup_with_prohibited <0/1>\n");
exit(1);
}
value = (t_u16)A2HEXDECIMAL(argv[4]);
}
/* setup higher/lower mac */
else if (!strcmp(argv[3], "higher_lower_mac")) {
cmd_len += sizeof(t_u16);
action = ACTION_TDLS_DEBUG_HIGHER_LOWER_MAC;
if (argc < 5) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_debug higher_lower_mac <0/1>\n");
exit(1);
}
value = (t_u16)A2HEXDECIMAL(argv[4]);
}
/* ignore key lifetime expiry */
else if (!strcmp(argv[3], "ignore_key_expiry")) {
cmd_len += sizeof(t_u16);
action = ACTION_TDLS_DEBUG_IGNORE_KEY_EXPIRY;
if (argc < 5) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_debug ignore_key_expiry <0/1>\n");
exit(1);
}
value = (t_u16)A2HEXDECIMAL(argv[4]);
}
/* allow weak security */
else if (!strcmp(argv[3], "allow_weak_security")) {
cmd_len += sizeof(t_u16);
action = ACTION_TDLS_DEBUG_ALLOW_WEAK_SECURITY;
if (argc < 5) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_debug allow_weak_security <0/1>\n");
exit(1);
}
value = (t_u16)A2HEXDECIMAL(argv[4]);
}
/* stop RX */
else if (!strcmp(argv[3], "stop_rx")) {
cmd_len += sizeof(t_u16);
action = ACTION_TDLS_DEBUG_STOP_RX;
if (argc < 5) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_debug stop_rx <0/1>\n");
exit(1);
}
value = (t_u16)A2HEXDECIMAL(argv[4]);
}
/* Immediate return */
else if (!strcmp(argv[3], "cs_im_return")) {
cmd_len += sizeof(t_u16);
action = ACTION_TDLS_DEBUG_CS_RET_IM;
if (argc < 5) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX tdls_debug cs_im_return <0/1>\n");
exit(1);
}
value = (t_u16)A2HEXDECIMAL(argv[4]);
} else {
printf("ERR:Incorrect command!\n");
exit(1);
}
buffer = (t_u8 *)malloc(cmd_len);
if (!buffer) {
printf("ERR:Cannot allocate memory!\n");
return -1;
}
memset(buffer, 0, cmd_len);
param_buf = (tdls_debug *)buffer;
param_buf->action = action;
memcpy(param_buf->data, &value, sizeof(value));
hexdump("tdls_debug", buffer, cmd_len, ' ');
/* Send collective command */
ret = tdls_ioctl((t_u8 *)buffer, cmd_len);
/* Process response */
if (ret == MLAN_STATUS_SUCCESS) {
printf("TDLS debug request successful.\n");
} else {
printf("ERR:TDLS debug request failed.\n");
}
if (buffer)
free(buffer);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process tdls idle time set/get
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_tdls_idle_time(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
int tdls_idle_time = 0;
/* Check arguments */
if (argc < 3 || argc > 4) {
printf("ERR:Incorrect number of arguments!\n");
printf("Syntax: ./mlanutl mlanX tdls_idle_time <time>\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: tdls_idle_time fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
tdls_idle_time = *(int *)buffer;
printf("TDLS idle time: %d\n", tdls_idle_time);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/** custom IE, auto mask value */
#define CUSTOM_IE_AUTO_MASK 0xffff
/**
* @brief Show usage information for the customie
* command
*
* $return N/A
**/
void
print_custom_ie_usage(void)
{
printf("\nUsage : customie [INDEX] [MASK] [IEBuffer]");
printf("\n empty - Get all IE settings\n");
printf("\n INDEX: 0 - Get/Set IE index 0 setting");
printf("\n 1 - Get/Set IE index 1 setting");
printf("\n 2 - Get/Set IE index 2 setting");
printf("\n 3 - Get/Set IE index 3 setting");
printf("\n . ");
printf("\n . ");
printf("\n . ");
printf("\n -1 - Append/Delete IE automatically");
printf("\n Delete will delete the IE from the matching IE buffer");
printf("\n Append will append the IE to the buffer with the same mask");
printf("\n MASK : Management subtype mask value as per bit defintions");
printf("\n : Bit 0 - Association request.");
printf("\n : Bit 1 - Association response.");
printf("\n : Bit 2 - Reassociation request.");
printf("\n : Bit 3 - Reassociation response.");
printf("\n : Bit 4 - Probe request.");
printf("\n : Bit 5 - Probe response.");
printf("\n : Bit 8 - Beacon.");
printf("\n MASK : MASK = 0 to clear the mask and the IE buffer");
printf("\n IEBuffer : IE Buffer in hex (max 256 bytes)\n\n");
return;
}
/**
* @brief Creates a hostcmd request for custom IE settings
* and sends to the driver
*
* Usage: "customie [INDEX] [MASK] [IEBuffer]"
*
* Options: INDEX : 0 - Get/Delete IE index 0 setting
* 1 - Get/Delete IE index 1 setting
* 2 - Get/Delete IE index 2 setting
* 3 - Get/Delete IE index 3 setting
* .
* .
* .
* -1 - Append IE at the IE buffer with same MASK
* MASK : Management subtype mask value
* IEBuffer: IE Buffer in hex
* empty - Get all IE settings
*
* @param argc Number of arguments
* @param argv Pointer to the arguments
* @return N/A
**/
static int
process_customie(int argc, char *argv[])
{
eth_priv_ds_misc_custom_ie *tlv = NULL;
tlvbuf_max_mgmt_ie *max_mgmt_ie_tlv = NULL;
t_u16 mgmt_subtype_mask = 0;
custom_ie *ie_ptr = NULL;
int ie_buf_len = 0, ie_len = 0, i = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], 0, NULL);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* mlanutl mlan0 customie idx flag buf */
if (argc > 6) {
printf("ERR:Too many arguments.\n");
print_custom_ie_usage();
return MLAN_STATUS_FAILURE;
}
/* Error checks and initialize the command length */
if (argc > 3) {
if (((IS_HEX_OR_DIGIT(argv[3]) == MLAN_STATUS_FAILURE) &&
(atoi(argv[3]) != -1)) || (atoi(argv[3]) < -1)) {
printf("ERR:Illegal index %s\n", argv[3]);
print_custom_ie_usage();
return MLAN_STATUS_FAILURE;
}
}
switch (argc) {
case 3:
break;
case 4:
if (atoi(argv[3]) < 0) {
printf("ERR:Illegal index %s. Must be either greater than or equal to 0 for Get Operation \n", argv[3]);
print_custom_ie_usage();
return MLAN_STATUS_FAILURE;
}
break;
case 5:
if (MLAN_STATUS_FAILURE == ishexstring(argv[4]) ||
A2HEXDECIMAL(argv[4]) != 0) {
printf("ERR: Mask value should be 0 to clear IEBuffers.\n");
print_custom_ie_usage();
return MLAN_STATUS_FAILURE;
}
if (atoi(argv[3]) == -1) {
printf("ERR: You must provide buffer for automatic deletion.\n");
print_custom_ie_usage();
return MLAN_STATUS_FAILURE;
}
break;
case 6:
/* This is to check negative numbers and special symbols */
if (MLAN_STATUS_FAILURE == IS_HEX_OR_DIGIT(argv[4])) {
printf("ERR:Mask value must be 0 or hex digits\n");
print_custom_ie_usage();
return MLAN_STATUS_FAILURE;
}
/* If above check is passed and mask is not hex, then it must be 0 */
if ((ISDIGIT(argv[4]) == MLAN_STATUS_SUCCESS) && atoi(argv[4])) {
printf("ERR:Mask value must be 0 or hex digits\n ");
print_custom_ie_usage();
return MLAN_STATUS_FAILURE;
}
if (MLAN_STATUS_FAILURE == ishexstring(argv[5])) {
printf("ERR:Only hex digits are allowed\n");
print_custom_ie_usage();
return MLAN_STATUS_FAILURE;
}
ie_buf_len = strlen(argv[5]);
if (!strncasecmp("0x", argv[5], 2)) {
ie_len = (ie_buf_len - 2 + 1) / 2;
argv[5] += 2;
} else
ie_len = (ie_buf_len + 1) / 2;
if (ie_len > MAX_IE_BUFFER_LEN) {
printf("ERR:Incorrect IE length %d\n", ie_buf_len);
print_custom_ie_usage();
return MLAN_STATUS_FAILURE;
}
mgmt_subtype_mask = (t_u16)A2HEXDECIMAL(argv[4]);
break;
}
/* Initialize the command buffer */
tlv = (eth_priv_ds_misc_custom_ie *)(buffer + strlen(CMD_MARVELL) +
strlen(argv[2]));
tlv->type = MRVL_MGMT_IE_LIST_TLV_ID;
if (argc == 3 || argc == 4) {
if (argc == 3)
tlv->len = 0;
else {
tlv->len = sizeof(t_u16);
ie_ptr = (custom_ie *)(tlv->ie_data);
ie_ptr->ie_index = (t_u16)(atoi(argv[3]));
}
} else {
/* Locate headers */
ie_ptr = (custom_ie *)(tlv->ie_data);
/* Set TLV fields */
tlv->len = sizeof(custom_ie) + ie_len;
ie_ptr->ie_index = atoi(argv[3]);
ie_ptr->mgmt_subtype_mask = mgmt_subtype_mask;
ie_ptr->ie_length = ie_len;
if (argc == 6)
string2raw(argv[5], ie_ptr->ie_buffer);
}
/* Initialize the ifr structure */
memset(&ifr, 0, sizeof(ifr));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
/* Perform ioctl */
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("ioctl[CUSTOM_IE_CFG]");
printf("ERR:Command sending failed!\n");
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Print response */
if (argc > 4) {
printf("Custom IE setting successful\n");
} else {
printf("Querying custom IE successful\n");
ie_len = tlv->len;
ie_ptr = (custom_ie *)(tlv->ie_data);
while (ie_len >= (int)sizeof(custom_ie)) {
printf("Index [%d]\n", ie_ptr->ie_index);
if (ie_ptr->ie_length)
printf("Management Subtype Mask = 0x%02x\n",
(ie_ptr->mgmt_subtype_mask) == 0 ?
CUSTOM_IE_AUTO_MASK :
(ie_ptr->mgmt_subtype_mask));
else
printf("Management Subtype Mask = 0x%02x\n",
(ie_ptr->mgmt_subtype_mask));
hexdump("IE Buffer", (void *)ie_ptr->ie_buffer,
ie_ptr->ie_length, ' ');
ie_len -= sizeof(custom_ie) + ie_ptr->ie_length;
ie_ptr = (custom_ie *)((t_u8 *)ie_ptr +
sizeof(custom_ie) +
ie_ptr->ie_length);
}
}
max_mgmt_ie_tlv = (tlvbuf_max_mgmt_ie *)((t_u8 *)tlv +
sizeof
(eth_priv_ds_misc_custom_ie) +
tlv->len);
if (max_mgmt_ie_tlv) {
if (max_mgmt_ie_tlv->type == MRVL_MAX_MGMT_IE_TLV_ID) {
for (i = 0; i < max_mgmt_ie_tlv->count; i++) {
printf("buf%d_size = %d\n", i,
max_mgmt_ie_tlv->info[i].buf_size);
printf("number of buffers = %d\n",
max_mgmt_ie_tlv->info[i].buf_count);
printf("\n");
}
}
}
if (buffer)
free(buffer);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process regrdwr command
*
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_regrdwr(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
struct eth_priv_ds_reg_rw *reg = NULL;
if (argc < 5 || argc > 6) {
printf("Error: invalid no of arguments\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: regrdwr fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
reg = (struct eth_priv_ds_reg_rw *)buffer;
if (argc == 5) {
/* GET operation */
printf("Value = 0x%x\n", reg->value);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process rdeeprom command
*
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_rdeeprom(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
struct eth_priv_ds_read_eeprom *eeprom = NULL;
int i = 0;
if (argc != 5) {
printf("Error: invalid no of arguments\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: rdeeprom fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
eeprom = (struct eth_priv_ds_read_eeprom *)buffer;
if (argc == 5) {
/* GET operation */
printf("Value:\n");
for (i = 0; i < MIN(MAX_EEPROM_DATA, eeprom->byte_count); i++)
printf(" %02x", eeprom->value[i]);
printf("\n");
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process memrdwr command
*
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_memrdwr(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
struct eth_priv_ds_mem_rw *mem = NULL;
if (argc < 4 || argc > 5) {
printf("Error: invalid no of arguments\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: memrdwr fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
mem = (struct eth_priv_ds_mem_rw *)buffer;
if (argc == 4) {
/* GET operation */
printf("Value = 0x%x\n", mem->value);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
#define STACK_NBYTES 100 /**< Number of bytes in stack */
#define MAX_BYTESEQ 6 /**< Maximum byte sequence */
#define TYPE_DNUM 1 /**< decimal number */
#define TYPE_BYTESEQ 2 /**< byte sequence */
#define MAX_OPERAND 0x40 /**< Maximum operands */
#define TYPE_EQ (MAX_OPERAND+1) /**< byte comparison: == operator */
#define TYPE_EQ_DNUM (MAX_OPERAND+2) /**< decimal comparison: =d operator */
#define TYPE_EQ_BIT (MAX_OPERAND+3) /**< bit comparison: =b operator */
#define TYPE_AND (MAX_OPERAND+4) /**< && operator */
#define TYPE_OR (MAX_OPERAND+5) /**< || operator */
typedef struct {
t_u16 sp; /**< Stack pointer */
t_u8 byte[STACK_NBYTES]; /**< Stack */
} mstack_t;
typedef struct {
t_u8 type; /**< Type */
t_u8 reserve[3]; /**< so 4-byte align val array */
/* byte sequence is the largest among all the operands and operators. */
/* byte sequence format: 1 byte of num of bytes, then variable num bytes */
t_u8 val[MAX_BYTESEQ + 1];/**< Value */
} op_t;
/**
* @brief push data to stack
*
* @param s a pointer to mstack_t structure
*
* @param nbytes number of byte to push to stack
*
* @param val a pointer to data buffer
*
* @return TRUE-- sucess , FALSE -- fail
*
*/
static int
push_n(mstack_t * s, t_u8 nbytes, t_u8 *val)
{
if ((s->sp + nbytes) < STACK_NBYTES) {
memcpy((void *)(s->byte + s->sp), (const void *)val,
(size_t) nbytes);
s->sp += nbytes;
/* printf("push: n %d sp %d\n", nbytes, s->sp); */
return TRUE;
} else /* stack full */
return FALSE;
}
/**
* @brief push data to stack
*
* @param s a pointer to mstack_t structure
*
* @param op a pointer to op_t structure
*
* @return TRUE-- sucess , FALSE -- fail
*
*/
static int
push(mstack_t * s, op_t * op)
{
t_u8 nbytes;
switch (op->type) {
case TYPE_DNUM:
if (push_n(s, 4, op->val))
return push_n(s, 1, &op->type);
return FALSE;
case TYPE_BYTESEQ:
nbytes = op->val[0];
if (push_n(s, nbytes, op->val + 1) &&
push_n(s, 1, op->val) && push_n(s, 1, &op->type))
return TRUE;
return FALSE;
default:
return push_n(s, 1, &op->type);
}
}
/**
* @brief parse RPN string
*
* @param s a pointer to Null-terminated string to scan.
*
* @param first_time a pointer to return first_time
*
* @return A pointer to the last token found in string.
* NULL is returned when there are no more tokens to be found.
*
*/
static char *
getop(char *s, int *first_time)
{
const char delim[] = " \t\n";
char *p;
if (*first_time) {
p = strtok(s, delim);
*first_time = FALSE;
} else {
p = strtok(NULL, delim);
}
return p;
}
/**
* @brief Verify hex digit.
*
* @param c input ascii char
* @param h a pointer to return integer value of the digit char.
* @return TURE -- c is hex digit, FALSE -- c is not hex digit.
*/
static int
ishexdigit(char c, t_u8 *h)
{
if (c >= '0' && c <= '9') {
*h = c - '0';
return TRUE;
} else if (c >= 'a' && c <= 'f') {
*h = c - 'a' + 10;
return TRUE;
} else if (c >= 'A' && c <= 'F') {
*h = c - 'A' + 10;
return TRUE;
}
return FALSE;
}
/**
* @brief convert hex string to integer.
*
* @param s A pointer to hex string, string length up to 2 digits.
* @return integer value.
*/
static t_u8
hex_atoi(char *s)
{
int i;
t_u8 digit; /* digital value */
t_u8 t = 0; /* total value */
for (i = 0, t = 0; ishexdigit(s[i], &digit) && i < 2; i++)
t = 16 * t + digit;
return t;
}
/**
* @brief Parse byte sequence in hex format string to a byte sequence.
*
* @param opstr A pointer to byte sequence in hex format string, with ':' as delimiter between two byte.
* @param val A pointer to return byte sequence string
* @return NA
*/
static void
parse_hex(char *opstr, t_u8 *val)
{
char delim = ':';
char *p;
char *q;
t_u8 i;
/* +1 is for skipping over the preceding h character. */
p = opstr + 1;
/* First byte */
val[1] = hex_atoi(p++);
/* Parse subsequent bytes. */
/* Each byte is preceded by the : character. */
for (i = 1; *p; i++) {
q = strchr(p, delim);
if (!q)
break;
p = q + 1;
val[i + 1] = hex_atoi(p);
}
/* Set num of bytes */
val[0] = i;
}
/**
* @brief str2bin, convert RPN string to binary format
*
* @param str A pointer to rpn string
* @param stack A pointer to mstack_t structure
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
str2bin(char *str, mstack_t * stack)
{
int first_time;
char *opstr;
op_t op; /* operator/operand */
int dnum;
int ret = MLAN_STATUS_SUCCESS;
memset(stack, 0, sizeof(mstack_t));
first_time = TRUE;
while ((opstr = getop(str, &first_time)) != NULL) {
if (isdigit(*opstr)) {
op.type = TYPE_DNUM;
dnum = cpu_to_le32(atoi(opstr));
memcpy((t_u8 *)op.val, &dnum, sizeof(dnum));
if (!push(stack, &op)) {
printf("push decimal number failed\n");
ret = MLAN_STATUS_FAILURE;
break;
}
} else if (*opstr == 'h') {
op.type = TYPE_BYTESEQ;
parse_hex(opstr, op.val);
if (!push(stack, &op)) {
printf("push byte sequence failed\n");
ret = MLAN_STATUS_FAILURE;
break;
}
} else if (!strcmp(opstr, "==")) {
op.type = TYPE_EQ;
if (!push(stack, &op)) {
printf("push byte cmp operator failed\n");
ret = MLAN_STATUS_FAILURE;
break;
}
} else if (!strcmp(opstr, "=d")) {
op.type = TYPE_EQ_DNUM;
if (!push(stack, &op)) {
printf("push decimal cmp operator failed\n");
ret = MLAN_STATUS_FAILURE;
break;
}
} else if (!strcmp(opstr, "=b")) {
op.type = TYPE_EQ_BIT;
if (!push(stack, &op)) {
printf("push bit cmp operator failed\n");
ret = MLAN_STATUS_FAILURE;
break;
}
} else if (!strcmp(opstr, "&&")) {
op.type = TYPE_AND;
if (!push(stack, &op)) {
printf("push AND operator failed\n");
ret = MLAN_STATUS_FAILURE;
break;
}
} else if (!strcmp(opstr, "||")) {
op.type = TYPE_OR;
if (!push(stack, &op)) {
printf("push OR operator failed\n");
ret = MLAN_STATUS_FAILURE;
break;
}
} else {
printf("Unknown operand\n");
ret = MLAN_STATUS_FAILURE;
break;
}
}
return ret;
}
#define FILTER_BYTESEQ TYPE_EQ /**< byte sequence */
#define FILTER_DNUM TYPE_EQ_DNUM /**< decimal number */
#define FILTER_BITSEQ TYPE_EQ_BIT /**< bit sequence */
#define FILTER_TEST (FILTER_BITSEQ+1) /**< test */
#define NAME_TYPE 1 /**< Field name 'type' */
#define NAME_PATTERN 2 /**< Field name 'pattern' */
#define NAME_OFFSET 3 /**< Field name 'offset' */
#define NAME_NUMBYTE 4 /**< Field name 'numbyte' */
#define NAME_REPEAT 5 /**< Field name 'repeat' */
#define NAME_BYTE 6 /**< Field name 'byte' */
#define NAME_MASK 7 /**< Field name 'mask' */
#define NAME_DEST 8 /**< Field name 'dest' */
static struct mef_fields {
char *name;
/**< Name */
t_s8 nameid;
/**< Name Id. */
} mef_fields[] = {
{
"type", NAME_TYPE}, {
"pattern", NAME_PATTERN}, {
"offset", NAME_OFFSET}, {
"numbyte", NAME_NUMBYTE}, {
"repeat", NAME_REPEAT}, {
"byte", NAME_BYTE}, {
"mask", NAME_MASK}, {
"dest", NAME_DEST}
};
/**
* @brief get filter data
*
* @param fp A pointer to file stream
* @param ln A pointer to line number
* @param buf A pointer to hostcmd data
* @param size A pointer to the return size of hostcmd buffer
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
mlan_get_filter_data(FILE * fp, int *ln, t_u8 *buf, t_u16 *size)
{
t_s32 errors = 0, i;
char line[256], *pos = NULL, *pos1 = NULL;
t_u16 type = 0;
t_u32 pattern = 0;
t_u16 repeat = 0;
t_u16 offset = 0;
char byte_seq[50];
char mask_seq[50];
t_u16 numbyte = 0;
t_s8 type_find = 0;
t_s8 pattern_find = 0;
t_s8 offset_find = 0;
t_s8 numbyte_find = 0;
t_s8 repeat_find = 0;
t_s8 byte_find = 0;
t_s8 mask_find = 0;
t_s8 dest_find = 0;
char dest_seq[50];
*size = 0;
while ((pos = mlan_config_get_line(fp, line, sizeof(line), ln))) {
if (strcmp(pos, "}") == 0) {
break;
}
pos1 = strchr(pos, '=');
if (pos1 == NULL) {
printf("Line %d: Invalid mef_filter line '%s'\n", *ln,
pos);
errors++;
continue;
}
*pos1++ = '\0';
for (i = 0; (t_u32)i < NELEMENTS(mef_fields); i++) {
if (strncmp
(pos, mef_fields[i].name,
strlen(mef_fields[i].name)) == 0) {
switch (mef_fields[i].nameid) {
case NAME_TYPE:
type = a2hex_or_atoi(pos1);
if ((type != FILTER_DNUM) &&
(type != FILTER_BYTESEQ)
&& (type != FILTER_BITSEQ) &&
(type != FILTER_TEST)) {
printf("Invalid filter type:%d\n", type);
return MLAN_STATUS_FAILURE;
}
type_find = 1;
break;
case NAME_PATTERN:
pattern = a2hex_or_atoi(pos1);
pattern_find = 1;
break;
case NAME_OFFSET:
offset = a2hex_or_atoi(pos1);
offset_find = 1;
break;
case NAME_NUMBYTE:
numbyte = a2hex_or_atoi(pos1);
numbyte_find = 1;
break;
case NAME_REPEAT:
repeat = a2hex_or_atoi(pos1);
repeat_find = 1;
break;
case NAME_BYTE:
memset(byte_seq, 0, sizeof(byte_seq));
strncpy(byte_seq, pos1,
(sizeof(byte_seq) - 1));
byte_find = 1;
break;
case NAME_MASK:
memset(mask_seq, 0, sizeof(mask_seq));
strncpy(mask_seq, pos1,
(sizeof(mask_seq) - 1));
mask_find = 1;
break;
case NAME_DEST:
memset(dest_seq, 0, sizeof(dest_seq));
strncpy(dest_seq, pos1,
(sizeof(dest_seq) - 1));
dest_find = 1;
break;
}
break;
}
}
if (i == NELEMENTS(mef_fields)) {
printf("Line %d: unknown mef field '%s'.\n",
*line, pos);
errors++;
}
}
if (type_find == 0) {
printf("Can not find filter type\n");
return MLAN_STATUS_FAILURE;
}
switch (type) {
case FILTER_DNUM:
if (!pattern_find || !offset_find || !numbyte_find) {
printf("Missing field for FILTER_DNUM: pattern=%d,offset=%d,numbyte=%d\n", pattern_find, offset_find, numbyte_find);
return MLAN_STATUS_FAILURE;
}
memset(line, 0, sizeof(line));
snprintf(line, sizeof(line), "%d %d %d =d ", pattern, offset,
numbyte);
break;
case FILTER_BYTESEQ:
if (!byte_find || !offset_find || !repeat_find) {
printf("Missing field for FILTER_BYTESEQ: byte=%d,offset=%d,repeat=%d\n", byte_find, offset_find, repeat_find);
return MLAN_STATUS_FAILURE;
}
memset(line, 0, sizeof(line));
snprintf(line, sizeof(line), "%d h%s %d == ", repeat, byte_seq,
offset);
break;
case FILTER_BITSEQ:
if (!byte_find || !offset_find || !mask_find) {
printf("Missing field for FILTER_BITSEQ: byte=%d,offset=%d,mask_find=%d\n", byte_find, offset_find, mask_find);
return MLAN_STATUS_FAILURE;
}
if (strlen(byte_seq) != strlen(mask_seq)) {
printf("byte string's length is different with mask's length!\n");
return MLAN_STATUS_FAILURE;
}
memset(line, 0, sizeof(line));
snprintf(line, sizeof(line), "h%s %d h%s =b ", byte_seq, offset,
mask_seq);
break;
case FILTER_TEST:
if (!byte_find || !offset_find || !repeat_find || !dest_find) {
printf("Missing field for FILTER_TEST: byte=%d,offset=%d,repeat=%d,dest=%d\n", byte_find, offset_find, repeat_find, dest_find);
return MLAN_STATUS_FAILURE;
}
memset(line, 0, sizeof(line));
snprintf(line, sizeof(line), "h%s %d h%s %d ", dest_seq, repeat,
byte_seq, offset);
break;
}
memcpy(buf, line, strlen(line));
*size = strlen(line);
return MLAN_STATUS_SUCCESS;
}
#define NAME_MODE 1 /**< Field name 'mode' */
#define NAME_ACTION 2 /**< Field name 'action' */
#define NAME_FILTER_NUM 3 /**< Field name 'filter_num' */
#define NAME_RPN 4 /**< Field name 'RPN' */
static struct mef_entry_fields {
char *name;
/**< Name */
t_s8 nameid;
/**< Name id */
} mef_entry_fields[] = {
{
"mode", NAME_MODE}, {
"action", NAME_ACTION}, {
"filter_num", NAME_FILTER_NUM}, {
"RPN", NAME_RPN},};
typedef struct _MEF_ENTRY {
/** Mode */
t_u8 Mode;
/** Size */
t_u8 Action;
/** Size of expression */
t_u16 ExprSize;
} MEF_ENTRY;
/**
* @brief get mef_entry data
*
* @param fp A pointer to file stream
* @param ln A pointer to line number
* @param buf A pointer to hostcmd data
* @param size A pointer to the return size of hostcmd buffer
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
mlan_get_mef_entry_data(FILE * fp, int *ln, t_u8 *buf, t_u16 *size)
{
char line[256], *pos = NULL, *pos1 = NULL;
t_u8 mode, action, filter_num = 0;
char rpn[256];
t_s8 mode_find = 0;
t_s8 action_find = 0;
t_s8 filter_num_find = 0;
t_s8 rpn_find = 0;
char rpn_str[256];
int rpn_len = 0;
char filter_name[50];
t_s8 name_found = 0;
t_u16 len = 0;
int i;
int first_time = TRUE;
char *opstr = NULL;
char filter_action[10];
t_s32 errors = 0;
MEF_ENTRY *pMefEntry = (MEF_ENTRY *) buf;
mstack_t stack;
while ((pos = mlan_config_get_line(fp, line, sizeof(line), ln))) {
if (strcmp(pos, "}") == 0) {
break;
}
pos1 = strchr(pos, '=');
if (pos1 == NULL) {
printf("Line %d: Invalid mef_entry line '%s'\n", *ln,
pos);
errors++;
continue;
}
*pos1++ = '\0';
if (!mode_find || !action_find || !filter_num_find || !rpn_find) {
for (i = 0;
(unsigned int)i < NELEMENTS(mef_entry_fields);
i++) {
if (strncmp
(pos, mef_entry_fields[i].name,
strlen(mef_entry_fields[i].name)) == 0) {
switch (mef_entry_fields[i].nameid) {
case NAME_MODE:
mode = a2hex_or_atoi(pos1);
if (mode & ~0x7) {
printf("invalid mode=%d\n", mode);
return MLAN_STATUS_FAILURE;
}
pMefEntry->Mode = mode;
mode_find = 1;
break;
case NAME_ACTION:
action = a2hex_or_atoi(pos1);
if (action & ~0xff) {
printf("invalid action=%d\n", action);
return MLAN_STATUS_FAILURE;
}
pMefEntry->Action = action;
action_find = 1;
break;
case NAME_FILTER_NUM:
filter_num =
a2hex_or_atoi(pos1);
filter_num_find = 1;
break;
case NAME_RPN:
memset(rpn, 0, sizeof(rpn));
strncpy(rpn, pos1,
(sizeof(rpn) - 1));
rpn_find = 1;
break;
}
break;
}
}
if (i == NELEMENTS(mef_fields)) {
printf("Line %d: unknown mef_entry field '%s'.\n", *line, pos);
return MLAN_STATUS_FAILURE;
}
}
if (mode_find && action_find && filter_num_find && rpn_find) {
for (i = 0; i < filter_num; i++) {
opstr = getop(rpn, &first_time);
if (opstr == NULL)
break;
snprintf(filter_name, sizeof(filter_name),
"%s={", opstr);
name_found = 0;
while ((pos =
mlan_config_get_line(fp, line,
sizeof(line),
ln))) {
if (strncmp
(pos, filter_name,
strlen(filter_name)) == 0) {
name_found = 1;
break;
}
}
if (!name_found) {
fprintf(stderr,
"mlanutl: %s not found in file\n",
filter_name);
return MLAN_STATUS_FAILURE;
}
if (MLAN_STATUS_FAILURE ==
mlan_get_filter_data(fp, ln,
(t_u8 *)(rpn_str +
rpn_len),
&len))
break;
rpn_len += len;
if (i > 0) {
memcpy(rpn_str + rpn_len, filter_action,
strlen(filter_action));
rpn_len += strlen(filter_action);
}
opstr = getop(rpn, &first_time);
if (opstr == NULL)
break;
memset(filter_action, 0, sizeof(filter_action));
snprintf(filter_action, sizeof(filter_action),
"%s ", opstr);
}
/* Remove the last space */
if (rpn_len > 0) {
rpn_len--;
rpn_str[rpn_len] = 0;
}
if (MLAN_STATUS_FAILURE == str2bin(rpn_str, &stack)) {
printf("Fail on str2bin!\n");
return MLAN_STATUS_FAILURE;
}
*size = sizeof(MEF_ENTRY);
pMefEntry->ExprSize = cpu_to_le16(stack.sp);
memmove(buf + sizeof(MEF_ENTRY), stack.byte, stack.sp);
*size += stack.sp;
break;
} else if (mode_find && action_find && filter_num_find &&
(filter_num == 0)) {
pMefEntry->ExprSize = 0;
*size = sizeof(MEF_ENTRY);
break;
}
}
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process enable/disable DFS offload
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_dfs_offload_enable(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Check arguments */
if (argc < 3 || argc > 4) {
printf("ERR:Incorrect number of arguments!\n");
printf("Syntax: ./mlanutl mlanX dfs_offload <0/1>\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: dfs offload enable/disable fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
#define MEFCFG_CMDCODE 0x009a
/**
* @brief Process mefcfg command
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_mefcfg(int argc, char *argv[])
{
char line[256], cmdname[256], *pos = NULL;
int cmdname_found = 0, name_found = 0;
int ln = 0;
int ret = MLAN_STATUS_SUCCESS;
int i;
t_u8 *buffer = NULL;
t_u16 len = 0;
HostCmd_DS_MEF_CFG *mefcmd = NULL;
HostCmd_DS_GEN *hostcmd = NULL;
FILE *fp = NULL;
t_u32 cmd_len = 0, cmd_header_len;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
if (argc < 4) {
printf("Error: invalid no of arguments\n");
printf("Syntax: ./mlanutl mlan0 mefcfg <mef.conf>\n");
exit(1);
}
cmd_header_len = strlen(CMD_MARVELL) + strlen("HOSTCMD");
cmd_len = sizeof(HostCmd_DS_GEN) + sizeof(HostCmd_DS_MEF_CFG);
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (buffer == NULL) {
fprintf(stderr, "Cannot alloc memory\n");
exit(1);
}
memset(buffer, 0, BUFFER_LENGTH);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* buf = MRVL_CMD<cmd> */
prepare_buffer(buffer, HOSTCMD, 0, NULL);
/* buf = MRVL_CMD<cmd><hostcmd_size><HostCmd_DS_GEN> */
hostcmd = (HostCmd_DS_GEN *)(buffer + cmd_header_len + sizeof(t_u32));
hostcmd->command = cpu_to_le16(MEFCFG_CMDCODE);
hostcmd->seq_num = 0;
hostcmd->result = 0;
/* buf = MRVL_CMD<cmd><hostcmd_size><HostCmd_DS_GEN><HostCmd_DS_MEF_CFG> */
mefcmd = (HostCmd_DS_MEF_CFG *)(buffer + cmd_header_len +
sizeof(t_u32) + S_DS_GEN);
/* Host Command Population */
snprintf(cmdname, sizeof(cmdname), "%s={", argv[2]);
cmdname_found = 0;
fp = fopen(argv[3], "r");
if (fp == NULL) {
fprintf(stderr, "Cannot open file %s\n", argv[4]);
exit(1);
}
while ((pos = mlan_config_get_line(fp, line, sizeof(line), &ln))) {
if (strcmp(pos, cmdname) == 0) {
cmdname_found = 1;
snprintf(cmdname, sizeof(cmdname), "Criteria=");
name_found = 0;
while ((pos =
mlan_config_get_line(fp, line, sizeof(line),
&ln))) {
if (strncmp(pos, cmdname, strlen(cmdname)) == 0) {
name_found = 1;
mefcmd->Criteria =
a2hex_or_atoi(pos +
strlen(cmdname));
break;
}
}
if (!name_found) {
fprintf(stderr,
"mlanutl: criteria not found in file '%s'\n",
argv[3]);
break;
}
snprintf(cmdname, sizeof(cmdname), "NumEntries=");
name_found = 0;
while ((pos =
mlan_config_get_line(fp, line, sizeof(line),
&ln))) {
if (strncmp(pos, cmdname, strlen(cmdname)) == 0) {
name_found = 1;
mefcmd->NumEntries =
a2hex_or_atoi(pos +
strlen(cmdname));
break;
}
}
if (!name_found) {
fprintf(stderr,
"mlanutl: NumEntries not found in file '%s'\n",
argv[3]);
break;
}
for (i = 0; i < mefcmd->NumEntries; i++) {
snprintf(cmdname, sizeof(cmdname),
"mef_entry_%d={", i);
name_found = 0;
while ((pos =
mlan_config_get_line(fp, line,
sizeof(line),
&ln))) {
if (strncmp
(pos, cmdname,
strlen(cmdname)) == 0) {
name_found = 1;
break;
}
}
if (!name_found) {
fprintf(stderr,
"mlanutl: %s not found in file '%s'\n",
cmdname, argv[3]);
break;
}
if (MLAN_STATUS_FAILURE ==
mlan_get_mef_entry_data(fp, &ln,
(t_u8 *)hostcmd +
cmd_len, &len)) {
ret = MLAN_STATUS_FAILURE;
break;
}
cmd_len += len;
}
break;
}
}
fclose(fp);
/* buf = MRVL_CMD<cmd><hostcmd_size> */
memcpy(buffer + cmd_header_len, (t_u8 *)&cmd_len, sizeof(t_u32));
if (!cmdname_found)
fprintf(stderr,
"mlanutl: cmdname '%s' not found in file '%s'\n",
argv[4], argv[3]);
if (!cmdname_found || !name_found) {
ret = MLAN_STATUS_FAILURE;
goto mef_exit;
}
hostcmd->size = cpu_to_le16(cmd_len);
mefcmd->Criteria = cpu_to_le32(mefcmd->Criteria);
mefcmd->NumEntries = cpu_to_le16(mefcmd->NumEntries);
hexdump("mefcfg", buffer + cmd_header_len, cmd_len, ' ');
/* Initialize the ifr structure */
memset(&ifr, 0, sizeof(ifr));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
/* Perform ioctl */
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("ioctl[MEF_CFG]");
printf("ERR:Command sending failed!\n");
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_FAILURE;
}
ret = process_host_cmd_resp(HOSTCMD, buffer);
mef_exit:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#ifdef STA_SUPPORT
/**
* @brief Prepare ARP filter buffer
* @param fp File handler
* @param buf A pointer to the buffer
* @param length A pointer to the length of buffer
* @param cmd_header_len Command header length
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
int
prepare_arp_filter_buffer(FILE * fp, t_u8 *buf, t_u16 *length,
int cmd_header_len)
{
char line[256], *pos = NULL;
int ln = 0;
int ret = MLAN_STATUS_SUCCESS;
int arpfilter_found = 0;
memset(buf, 0, BUFFER_LENGTH - cmd_header_len - sizeof(t_u32));
while ((pos = mlan_config_get_line(fp, line, sizeof(line), &ln))) {
if (strcmp(pos, "arpfilter={") == 0) {
arpfilter_found = 1;
mlan_get_hostcmd_data(fp, &ln, buf, length);
break;
}
}
if (!arpfilter_found) {
fprintf(stderr, "mlanutl: 'arpfilter' not found in conf file");
ret = MLAN_STATUS_FAILURE;
}
return ret;
}
/**
* @brief Process arpfilter
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_arpfilter(int argc, char *argv[])
{
t_u8 *buffer = NULL;
t_u16 length = 0;
int ret = MLAN_STATUS_SUCCESS;
FILE *fp = NULL;
int cmd_header_len = 0;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
if (argc < 4) {
printf("Error: invalid no of arguments\n");
printf("Syntax: ./mlanutl mlanX arpfilter <arpfilter.conf>\n");
exit(1);
}
cmd_header_len = strlen(CMD_MARVELL) + strlen(argv[2]);
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (buffer == NULL) {
printf("Error: allocate memory for arpfilter failed\n");
return -ENOMEM;
}
memset(buffer, 0, BUFFER_LENGTH);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* buf = MRVL_CMD<cmd> */
prepare_buffer(buffer, argv[2], 0, NULL);
/* Reading the configuration file */
fp = fopen(argv[3], "r");
if (fp == NULL) {
fprintf(stderr, "Cannot open file %s\n", argv[3]);
ret = MLAN_STATUS_FAILURE;
goto arp_exit;
}
ret = prepare_arp_filter_buffer(fp,
buffer + cmd_header_len + sizeof(t_u32),
&length, cmd_header_len);
fclose(fp);
if (ret == MLAN_STATUS_FAILURE)
goto arp_exit;
/* buf = MRVL_CMD<cmd><hostcmd_size> */
memcpy(buffer + cmd_header_len, &length, sizeof(length));
/* Initialize the ifr structure */
memset(&ifr, 0, sizeof(ifr));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
/* Perform ioctl */
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("ioctl[ARP_FILTER]");
printf("ERR:Command sending failed!\n");
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_FAILURE;
}
arp_exit:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#endif /* STA_SUPPORT */
/**
* @brief parse hex data
* @param fp File handler
* @param dst A pointer to receive hex data
* @return length of hex data
*/
int
fparse_for_hex(FILE * fp, t_u8 *dst)
{
char *ptr = NULL;
t_u8 *dptr = NULL;
char buf[256];
dptr = dst;
while (fgets(buf, sizeof(buf), fp)) {
ptr = buf;
while (*ptr) {
/* skip leading spaces */
while (*ptr && (isspace(*ptr) || *ptr == '\t'))
ptr++;
/* skip blank lines and lines beginning with '#' */
if (*ptr == '\0' || *ptr == '#')
break;
if (isxdigit(*ptr)) {
ptr = convert2hex(ptr, dptr++);
} else {
/* Invalid character on data line */
ptr++;
}
}
}
return dptr - dst;
}
/** Config data header length */
#define CFG_DATA_HEADER_LEN 6
/**
* @brief Prepare cfg-data buffer
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @param fp File handler
* @param buf A pointer to comand buffer
* @param cmd_header_len Length of the command header
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
int
prepare_cfg_data_buffer(int argc, char *argv[], FILE * fp, t_u8 *buf,
int cmd_header_len)
{
int ln = 0, type;
HostCmd_DS_GEN *hostcmd = NULL;
HostCmd_DS_802_11_CFG_DATA *pcfg_data = NULL;
memset(buf, 0, BUFFER_LENGTH - cmd_header_len - sizeof(t_u32));
hostcmd = (HostCmd_DS_GEN *)buf;
hostcmd->command = cpu_to_le16(HostCmd_CMD_CFG_DATA);
pcfg_data = (HostCmd_DS_802_11_CFG_DATA *)(buf + S_DS_GEN);
pcfg_data->action =
(argc == 4) ? HostCmd_ACT_GEN_GET : HostCmd_ACT_GEN_SET;
type = atoi(argv[3]);
if ((type < 1) || (type > 2)) {
fprintf(stderr, "mlanutl: Invalid register type\n");
return MLAN_STATUS_FAILURE;
} else {
pcfg_data->type = type;
}
if (argc == 5) {
ln = fparse_for_hex(fp, pcfg_data->data);
}
pcfg_data->data_len = ln;
hostcmd->size =
cpu_to_le16(pcfg_data->data_len + S_DS_GEN +
CFG_DATA_HEADER_LEN);
pcfg_data->data_len = cpu_to_le16(pcfg_data->data_len);
pcfg_data->type = cpu_to_le16(pcfg_data->type);
pcfg_data->action = cpu_to_le16(pcfg_data->action);
hostcmd->seq_num = 0;
hostcmd->result = 0;
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process cfgdata
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_cfgdata(int argc, char *argv[])
{
t_u8 *buffer = NULL;
HostCmd_DS_GEN *hostcmd = NULL;
int ret = MLAN_STATUS_SUCCESS;
FILE *fp = NULL;
int cmd_header_len = 0;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
if (argc < 4 || argc > 5) {
printf("Error: invalid no of arguments\n");
printf("Syntax: ./mlanutl mlanX cfgdata <register type> <filename>\n");
exit(1);
}
if (argc == 5) {
fp = fopen(argv[4], "r");
if (fp == NULL) {
fprintf(stderr, "Cannot open file %s\n", argv[3]);
exit(1);
}
}
cmd_header_len = strlen(CMD_MARVELL) + strlen(HOSTCMD);
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (buffer == NULL) {
printf("Error: allocate memory for hostcmd failed\n");
if (argc == 5)
fclose(fp);
return -ENOMEM;
}
memset(buffer, 0, BUFFER_LENGTH);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
memset(cmd, 0, sizeof(struct eth_priv_cmd));
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* buf = MRVL_CMD<cmd> */
prepare_buffer(buffer, HOSTCMD, 0, NULL);
/* buf = MRVL_CMD<cmd><hostcmd_size><HostCmd_DS_GEN> */
hostcmd = (HostCmd_DS_GEN *)(buffer + cmd_header_len + sizeof(t_u32));
ret = prepare_cfg_data_buffer(argc, argv, fp, (t_u8 *)hostcmd,
cmd_header_len);
if (argc == 5)
fclose(fp);
if (ret == MLAN_STATUS_FAILURE)
goto _exit_;
/* Initialize the ifr structure */
memset(&ifr, 0, sizeof(ifr));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
/* Perform ioctl */
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("ioctl[CFG_DATA]");
printf("ERR:Command sending failed!\n");
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_FAILURE;
}
ret = process_host_cmd_resp(HOSTCMD, buffer);
_exit_:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Process transmission of mgmt frames
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_mgmtframetx(int argc, char *argv[])
{
struct ifreq ifr;
char *line = NULL;
FILE *config_file = NULL;
int li = 0, arg_num = 0, ret = 0, i = 0;
char *args[100], *pos = NULL, mac_addr[20];
t_u8 peer_mac[ETH_ALEN];
t_u16 data_len = 0, type = 0, subtype = 0;
t_u16 seq_num = 0, frag_num = 0, from_ds = 0, to_ds = 0;
eth_priv_mgmt_frame_tx *pmgmt_frame = NULL;
t_u8 *buffer = NULL;
pkt_header *hdr = NULL;
/* Check arguments */
if (argc != 4) {
printf("ERR:Incorrect number of arguments.\n");
printf("Syntax: ./mlanutl mlanX mgmtframetx <config/mgmt_frame.conf>\n");
exit(1);
}
data_len = sizeof(eth_priv_mgmt_frame_tx);
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate memory!\n");
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
hdr = (pkt_header *)buffer;
pmgmt_frame = (eth_priv_mgmt_frame_tx *)(buffer + sizeof(pkt_header));
/* Check if file exists */
config_file = fopen(argv[3], "r");
if (config_file == NULL) {
printf("\nERR:Config file can not open.\n");
goto done;
}
line = (char *)malloc(MAX_CONFIG_LINE);
if (!line) {
printf("ERR:Cannot allocate memory for line\n");
goto done;
}
memset(line, 0, MAX_CONFIG_LINE);
/* Parse file and process */
while (config_get_line(line, MAX_CONFIG_LINE, config_file, &li, &pos)) {
arg_num = parse_line(line, args);
if (strcmp(args[0], "PktType") == 0) {
type = (t_u16)A2HEXDECIMAL(args[1]);
pmgmt_frame->frm_ctl = (type & 0x3) << 2;
} else if (strcmp(args[0], "PktSubType") == 0) {
subtype = (t_u16)A2HEXDECIMAL(args[1]);
pmgmt_frame->frm_ctl |= subtype << 4;
} else if (strncmp(args[0], "Addr", 4) == 0) {
strncpy(mac_addr, args[1], 20);
ret = mac2raw(mac_addr, peer_mac);
if (ret != MLAN_STATUS_SUCCESS) {
printf("%s Address \n",
ret ==
MLAN_STATUS_FAILURE ? "Invalid MAC" : ret
==
MAC_BROADCAST ? "Broadcast" :
"Multicast");
if (ret == MLAN_STATUS_FAILURE)
goto done;
}
i = atoi(args[0] + 4);
switch (i) {
case 1:
memcpy(pmgmt_frame->addr1, peer_mac, ETH_ALEN);
break;
case 2:
memcpy(pmgmt_frame->addr2, peer_mac, ETH_ALEN);
break;
case 3:
memcpy(pmgmt_frame->addr3, peer_mac, ETH_ALEN);
break;
case 4:
memcpy(pmgmt_frame->addr4, peer_mac, ETH_ALEN);
break;
}
} else if (strcmp(args[0], "Data") == 0) {
for (i = 0; i < arg_num - 1; i++)
pmgmt_frame->payload[i] =
(t_u8)A2HEXDECIMAL(args[i + 1]);
data_len += arg_num - 1;
} else if (strcmp(args[0], "SeqNum") == 0) {
seq_num = (t_u16)A2HEXDECIMAL(args[1]);
pmgmt_frame->seq_ctl = seq_num << 4;
} else if (strcmp(args[0], "FragNum") == 0) {
frag_num = (t_u16)A2HEXDECIMAL(args[1]);
pmgmt_frame->seq_ctl |= frag_num;
} else if (strcmp(args[0], "FromDS") == 0) {
from_ds = (t_u16)A2HEXDECIMAL(args[1]);
pmgmt_frame->frm_ctl |= (from_ds & 0x1) << 9;
} else if (strcmp(args[0], "ToDS") == 0) {
to_ds = (t_u16)A2HEXDECIMAL(args[1]);
pmgmt_frame->frm_ctl |= (to_ds & 0x1) << 8;
}
}
pmgmt_frame->frm_len = data_len - sizeof(pmgmt_frame->frm_len);
#define MRVL_PKT_TYPE_MGMT_FRAME 0xE5
hdr->pkt_len = data_len;
hdr->TxPktType = MRVL_PKT_TYPE_MGMT_FRAME;
hdr->TxControl = 0;
hexdump("Frame Tx", buffer, data_len + sizeof(pkt_header), ' ');
/* Send collective command */
memset(&ifr, 0, sizeof(ifr));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)buffer;
/* Perform ioctl */
if (ioctl(sockfd, FRAME_TX_IOCTL, &ifr)) {
perror("");
printf("ERR:Could not send management frame.\n");
} else {
printf("Mgmt Frame sucessfully sent.\n");
}
done:
if (config_file)
fclose(config_file);
if (buffer)
free(buffer);
if (line)
free(line);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief set/get management frame passthrough
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_mgmt_frame_passthrough(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
t_u32 mask = 0;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: htcapinfo fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
mask = *(t_u32 *)buffer;
if (argc == 3)
printf("Registed Management Frame Mask: 0x%x\n", mask);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief read current command
* @param ptr A pointer to data
* @param curCmd A pointer to the buf which will hold current command
* @return NULL or the pointer to the left command buf
*/
static t_s8 *
readCurCmd(t_s8 *ptr, t_s8 *curCmd)
{
t_s32 i = 0;
#define MAX_CMD_SIZE 64 /**< Max command size */
while (*ptr != ']' && i < (MAX_CMD_SIZE - 1))
curCmd[i++] = *(++ptr);
if (*ptr != ']')
return NULL;
curCmd[i - 1] = '\0';
return ++ptr;
}
/**
* @brief parse command and hex data
* @param fp A pointer to FILE stream
* @param dst A pointer to the dest buf
* @param cmd A pointer to command buf for search
* @return Length of hex data or MLAN_STATUS_FAILURE
*/
static int
fparse_for_cmd_and_hex(FILE * fp, t_u8 *dst, t_u8 *cmd)
{
t_s8 *ptr;
t_u8 *dptr;
t_s8 buf[256], curCmd[64];
t_s32 isCurCmd = 0;
dptr = dst;
while (fgets((char *)buf, sizeof(buf), fp)) {
ptr = buf;
while (*ptr) {
/* skip leading spaces */
while (*ptr && isspace(*ptr))
ptr++;
/* skip blank lines and lines beginning with '#' */
if (*ptr == '\0' || *ptr == '#')
break;
if (*ptr == '[' && *(ptr + 1) != '/') {
ptr = readCurCmd(ptr, curCmd);
if (!ptr)
return MLAN_STATUS_FAILURE;
if (strcasecmp((char *)curCmd, (char *)cmd)) /* Not equal */
isCurCmd = 0;
else
isCurCmd = 1;
}
/* Ignore the rest if it is not correct cmd */
if (!isCurCmd)
break;
if (*ptr == '[' && *(ptr + 1) == '/')
return dptr - dst;
if (isxdigit(*ptr)) {
ptr = (t_s8 *)convert2hex((char *)ptr, dptr++);
} else {
/* Invalid character on data line */
ptr++;
}
}
}
return MLAN_STATUS_FAILURE;
}
/**
* @brief Send a WMM AC Queue configuration command to get/set/default params
*
* Configure or get the parameters of a WMM AC queue. The command takes
* an optional Queue Id as a last parameter. Without the queue id, all
* queues will be acted upon.
*
* mlanutl mlanX qconfig set msdu <lifetime in TUs> [Queue Id: 0-3]
* mlanutl mlanX qconfig get [Queue Id: 0-3]
* mlanutl mlanX qconfig def [Queue Id: 0-3]
*
* @param argc number of arguments
* @param argv A pointer to arguments array
*
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_qconfig(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
wlan_ioctl_wmm_queue_config_t queue_config_cmd;
mlan_wmm_ac_e ac_idx;
mlan_wmm_ac_e ac_idx_start;
mlan_wmm_ac_e ac_idx_stop;
int cmd_header_len = 0;
const char *ac_str_tbl[] = { "BK", "BE", "VI", "VO" };
if (argc < 4) {
fprintf(stderr, "Invalid number of parameters!\n");
return -EINVAL;
}
cmd_header_len = strlen(CMD_MARVELL) + strlen(argv[2]);
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (buffer == NULL) {
printf("Error: allocate memory for qconfig failed\n");
return -ENOMEM;
}
memset(buffer, 0, BUFFER_LENGTH);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* buf = MRVL_CMD<cmd> */
prepare_buffer(buffer, argv[2], 0, NULL);
memset(&queue_config_cmd, 0x00, sizeof(wlan_ioctl_wmm_queue_config_t));
/* Initialize the ifr structure */
memset(&ifr, 0, sizeof(ifr));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (strcmp(argv[3], "get") == 0) {
/* 3 4 5 */
/* qconfig get [qid] */
if (argc == 4) {
ac_idx_start = WMM_AC_BK;
ac_idx_stop = WMM_AC_VO;
} else if (argc == 5) {
if (atoi(argv[4]) < WMM_AC_BK ||
atoi(argv[4]) > WMM_AC_VO) {
fprintf(stderr, "ERROR: Invalid Queue ID!\n");
return -EINVAL;
}
ac_idx_start = atoi(argv[4]);
ac_idx_stop = ac_idx_start;
} else {
fprintf(stderr, "Invalid number of parameters!\n");
return -EINVAL;
}
queue_config_cmd.action = WMM_QUEUE_CONFIG_ACTION_GET;
for (ac_idx = ac_idx_start; ac_idx <= ac_idx_stop; ac_idx++) {
queue_config_cmd.accessCategory = ac_idx;
memcpy(buffer + cmd_header_len,
(t_u8 *)&queue_config_cmd,
sizeof(queue_config_cmd));
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("qconfig ioctl");
} else {
memcpy((t_u8 *)&queue_config_cmd,
buffer + cmd_header_len,
sizeof(queue_config_cmd));
printf("qconfig %s(%d): MSDU Lifetime GET = 0x%04x (%d)\n", ac_str_tbl[ac_idx], ac_idx, queue_config_cmd.msduLifetimeExpiry, queue_config_cmd.msduLifetimeExpiry);
}
}
} else if (strcmp(argv[3], "set") == 0) {
if ((argc >= 5) && strcmp(argv[4], "msdu") == 0) {
/* 3 4 5 6 7 */
/* qconfig set msdu <value> [qid] */
if (argc == 6) {
ac_idx_start = WMM_AC_BK;
ac_idx_stop = WMM_AC_VO;
} else if (argc == 7) {
if (atoi(argv[6]) < WMM_AC_BK ||
atoi(argv[6]) > WMM_AC_VO) {
fprintf(stderr,
"ERROR: Invalid Queue ID!\n");
return -EINVAL;
}
ac_idx_start = atoi(argv[6]);
ac_idx_stop = ac_idx_start;
} else {
fprintf(stderr,
"Invalid number of parameters!\n");
return -EINVAL;
}
queue_config_cmd.action = WMM_QUEUE_CONFIG_ACTION_SET;
queue_config_cmd.msduLifetimeExpiry = atoi(argv[5]);
for (ac_idx = ac_idx_start; ac_idx <= ac_idx_stop;
ac_idx++) {
queue_config_cmd.accessCategory = ac_idx;
memcpy(buffer + cmd_header_len,
(t_u8 *)&queue_config_cmd,
sizeof(queue_config_cmd));
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("qconfig ioctl");
} else {
memcpy((t_u8 *)&queue_config_cmd,
buffer + cmd_header_len,
sizeof(queue_config_cmd));
printf("qconfig %s(%d): MSDU Lifetime SET = 0x%04x (%d)\n", ac_str_tbl[ac_idx], ac_idx, queue_config_cmd.msduLifetimeExpiry, queue_config_cmd.msduLifetimeExpiry);
}
}
} else {
/* Only MSDU Lifetime provisioning accepted for now */
fprintf(stderr, "Invalid set parameter: s/b [msdu]\n");
return -EINVAL;
}
} else if (strncmp(argv[3], "def", strlen("def")) == 0) {
/* 3 4 5 */
/* qconfig def [qid] */
if (argc == 4) {
ac_idx_start = WMM_AC_BK;
ac_idx_stop = WMM_AC_VO;
} else if (argc == 5) {
if (atoi(argv[4]) < WMM_AC_BK ||
atoi(argv[4]) > WMM_AC_VO) {
fprintf(stderr, "ERROR: Invalid Queue ID!\n");
return -EINVAL;
}
ac_idx_start = atoi(argv[4]);
ac_idx_stop = ac_idx_start;
} else {
fprintf(stderr, "Invalid number of parameters!\n");
return -EINVAL;
}
queue_config_cmd.action = WMM_QUEUE_CONFIG_ACTION_DEFAULT;
for (ac_idx = ac_idx_start; ac_idx <= ac_idx_stop; ac_idx++) {
queue_config_cmd.accessCategory = ac_idx;
memcpy(buffer + cmd_header_len,
(t_u8 *)&queue_config_cmd,
sizeof(queue_config_cmd));
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("qconfig ioctl");
} else {
memcpy((t_u8 *)&queue_config_cmd,
buffer + cmd_header_len,
sizeof(queue_config_cmd));
printf("qconfig %s(%d): MSDU Lifetime DEFAULT = 0x%04x (%d)\n", ac_str_tbl[ac_idx], ac_idx, queue_config_cmd.msduLifetimeExpiry, queue_config_cmd.msduLifetimeExpiry);
}
}
} else {
fprintf(stderr,
"Invalid qconfig command; s/b [set, get, default]\n");
return -EINVAL;
}
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Send an ADDTS command to the associated AP
*
* Process a given conf file for a specific TSPEC data block. Send the
* TSPEC along with any other IEs to the driver/firmware for transmission
* in an ADDTS request to the associated AP.
*
* Return the execution status of the command as well as the ADDTS response
* from the AP if any.
*
* mlanutl mlanX addts <filename.conf> <section# of tspec> <timeout in ms>
*
* @param argc number of arguments
* @param argv A pointer to arguments array
*
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_addts(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
wlan_ioctl_wmm_addts_req_t addtsReq;
FILE *fp = NULL;
char filename[48];
char config_id[20];
int cmd_header_len = 0, ret = 0, copy_len = 0;
memset(&addtsReq, 0x00, sizeof(addtsReq));
memset(filename, 0x00, sizeof(filename));
if (argc != 6) {
fprintf(stderr, "Invalid number of parameters!\n");
ret = -EINVAL;
goto done;
}
cmd_header_len = strlen(CMD_MARVELL) + strlen(argv[2]);
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (buffer == NULL) {
printf("Error: allocate memory for buffer failed\n");
ret = -ENOMEM;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* buf = MRVL_CMD<cmd> */
prepare_buffer(buffer, argv[2], 0, NULL);
strncpy(filename, argv[3], MIN(sizeof(filename) - 1, strlen(argv[3])));
fp = fopen(filename, "r");
if (fp == NULL) {
perror("fopen");
fprintf(stderr, "Cannot open file %s\n", argv[3]);
ret = -EFAULT;
goto done;
}
snprintf(config_id, sizeof(config_id), "tspec%d", atoi(argv[4]));
addtsReq.ieDataLen = fparse_for_cmd_and_hex(fp,
addtsReq.ieData,
(t_u8 *)config_id);
if (addtsReq.ieDataLen > 0) {
printf("Found %d bytes in the %s section of conf file %s\n",
(int)addtsReq.ieDataLen, config_id, filename);
} else {
fprintf(stderr, "section %s not found in %s\n",
config_id, filename);
ret = -EFAULT;
goto done;
}
addtsReq.timeout_ms = atoi(argv[5]);
printf("Cmd Input:\n");
hexdump(config_id, addtsReq.ieData, addtsReq.ieDataLen, ' ');
copy_len = sizeof(addtsReq);
memcpy(buffer + cmd_header_len, (t_u8 *)&addtsReq, copy_len);
/* Initialize the ifr structure */
memset(&ifr, 0, sizeof(ifr));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl: addts ioctl");
ret = -EFAULT;
goto done;
}
memcpy(&addtsReq, buffer, strlen((const char *)buffer));
printf("Cmd Output:\n");
printf("ADDTS Command Result = %d\n", addtsReq.commandResult);
printf("ADDTS IEEE Status = %d\n", addtsReq.ieeeStatusCode);
hexdump(config_id, addtsReq.ieData, addtsReq.ieDataLen, ' ');
done:
if (fp)
fclose(fp);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Send a DELTS command to the associated AP
*
* Process a given conf file for a specific TSPEC data block. Send the
* TSPEC along with any other IEs to the driver/firmware for transmission
* in a DELTS request to the associated AP.
*
* Return the execution status of the command. There is no response to a
* DELTS from the AP.
*
* mlanutl mlanX delts <filename.conf> <section# of tspec>
*
* @param argc number of arguments
* @param argv A pointer to arguments array
*
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_delts(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
wlan_ioctl_wmm_delts_req_t deltsReq;
FILE *fp = NULL;
char filename[48];
char config_id[20];
int cmd_header_len = 0, ret = 0, copy_len = 0;
memset(&deltsReq, 0x00, sizeof(deltsReq));
memset(filename, 0x00, sizeof(filename));
if (argc != 5) {
fprintf(stderr, "Invalid number of parameters!\n");
ret = -EINVAL;
goto done;
}
cmd_header_len = strlen(CMD_MARVELL) + strlen(argv[2]);
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (buffer == NULL) {
printf("Error: allocate memory for buffer failed\n");
ret = -ENOMEM;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* buf = MRVL_CMD<cmd> */
prepare_buffer(buffer, argv[2], 0, NULL);
strncpy(filename, argv[3], MIN(sizeof(filename) - 1, strlen(argv[3])));
fp = fopen(filename, "r");
if (fp == NULL) {
perror("fopen");
fprintf(stderr, "Cannot open file %s\n", argv[3]);
ret = -EFAULT;;
goto done;
}
snprintf(config_id, sizeof(config_id), "tspec%d", atoi(argv[4]));
deltsReq.ieDataLen = fparse_for_cmd_and_hex(fp,
deltsReq.ieData,
(t_u8 *)config_id);
if (deltsReq.ieDataLen > 0) {
printf("Found %d bytes in the %s section of conf file %s\n",
(int)deltsReq.ieDataLen, config_id, filename);
} else {
fprintf(stderr, "section %s not found in %s\n",
config_id, filename);
ret = -EFAULT;
goto done;
}
printf("Cmd Input:\n");
hexdump(config_id, deltsReq.ieData, deltsReq.ieDataLen, ' ');
copy_len =
sizeof(deltsReq) - sizeof(deltsReq.ieData) + deltsReq.ieDataLen;
memcpy(buffer + cmd_header_len, (t_u8 *)&deltsReq, copy_len);
/* Initialize the ifr structure */
memset(&ifr, 0, sizeof(ifr));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("delts ioctl");
ret = -EFAULT;
goto done;
}
memcpy(&deltsReq, buffer, strlen((const char *)buffer));
printf("Cmd Output:\n");
printf("DELTS Command Result = %d\n", deltsReq.commandResult);
done:
if (fp)
fclose(fp);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Get the current status of the WMM Queues
*
* Command: mlanutl mlanX qstatus
*
* Retrieve the following information for each AC if wmm is enabled:
* - WMM IE ACM Required
* - Firmware Flow Required
* - Firmware Flow Established
* - Firmware Queue Enabled
*
* @param argc number of arguments
* @param argv A pointer to arguments array
*
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_wmm_qstatus(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
wlan_ioctl_wmm_queue_status_t qstatus;
int ret = 0;
mlan_wmm_ac_e acVal;
if (argc != 3) {
fprintf(stderr, "Invalid number of parameters!\n");
ret = -EINVAL;
goto done;
}
memset(&qstatus, 0x00, sizeof(qstatus));
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (buffer == NULL) {
printf("Error: allocate memory for qconfig failed\n");
ret = -ENOMEM;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* buf = MRVL_CMD<cmd> */
prepare_buffer(buffer, argv[2], 0, NULL);
/* Initialize the ifr structure */
memset(&ifr, 0, sizeof(ifr));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("qstatus ioctl");
ret = -EFAULT;
goto done;
}
memcpy(&qstatus, buffer, strlen((const char *)buffer));
for (acVal = WMM_AC_BK; acVal <= WMM_AC_VO; acVal++) {
switch (acVal) {
case WMM_AC_BK:
printf("BK: ");
break;
case WMM_AC_BE:
printf("BE: ");
break;
case WMM_AC_VI:
printf("VI: ");
break;
case WMM_AC_VO:
printf("VO: ");
break;
default:
printf("??: ");
}
printf("ACM[%c], FlowReq[%c], FlowCreated[%c], Enabled[%c],"
" DE[%c], TE[%c]\n",
(qstatus.acStatus[acVal].wmmAcm ? 'X' : ' '),
(qstatus.acStatus[acVal].flowRequired ? 'X' : ' '),
(qstatus.acStatus[acVal].flowCreated ? 'X' : ' '),
(qstatus.acStatus[acVal].disabled ? ' ' : 'X'),
(qstatus.acStatus[acVal].deliveryEnabled ? 'X' : ' '),
(qstatus.acStatus[acVal].triggerEnabled ? 'X' : ' '));
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Get the current status of the WMM Traffic Streams
*
* Command: mlanutl mlanX ts_status
*
* @param argc number of arguments
* @param argv A pointer to arguments array
*
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_wmm_ts_status(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
wlan_ioctl_wmm_ts_status_t ts_status;
int tid;
int cmd_header_len = 0, ret = 0;
const char *ac_str_tbl[] = { "BK", "BE", "VI", "VO" };
if (argc != 3) {
fprintf(stderr, "Invalid number of parameters!\n");
ret = -EINVAL;
goto done;
}
cmd_header_len = strlen(CMD_MARVELL) + strlen(argv[2]);
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (buffer == NULL) {
printf("Error: allocate memory for qconfig failed\n");
ret = -ENOMEM;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* buf = MRVL_CMD<cmd> */
printf("\nTID Valid AC UP PSB FlowDir MediumTime\n");
printf("---------------------------------------------------\n");
for (tid = 0; tid <= 7; tid++) {
memset(buffer, 0, BUFFER_LENGTH);
prepare_buffer(buffer, argv[2], 0, NULL);
memset(&ts_status, 0x00, sizeof(ts_status));
ts_status.tid = tid;
/* Initialize the ifr structure */
memset(&ifr, 0, sizeof(ifr));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
memcpy(buffer + cmd_header_len, (t_u8 *)&ts_status,
sizeof(ts_status));
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("ts_status ioctl");
ret = -EFAULT;
goto done;
}
memcpy(&ts_status, buffer, strlen((const char *)buffer));
printf(" %02d %3s %2s %u %c ",
ts_status.tid,
(ts_status.valid ? "Yes" : "No"),
(ts_status.
valid ? ac_str_tbl[ts_status.accessCategory] : "--"),
ts_status.userPriority, (ts_status.psb ? 'U' : 'L'));
if ((ts_status.flowDir & 0x03) == 0) {
printf("%s", " ---- ");
} else {
printf("%2s%4s",
(ts_status.flowDir & 0x01 ? "Up" : ""),
(ts_status.flowDir & 0x02 ? "Down" : ""));
}
printf("%12u\n", ts_status.mediumTime);
}
printf("\n");
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Set/get WMM IE QoS info parameter
*
* @param argc number of arguments
* @param argv A pointer to arguments array
*
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_qos_config(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* Sanity tests */
if (argc < 3 || argc > 4) {
printf("Insufficient parameters\n");
printf("mlanutl mlanX qoscfg [QoS]\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: qoscfg fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
if (argc == 3) {
/* GET operation */
printf("WMM QoS Info: %#x\n", *buffer);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Set/get MAC control configuration
*
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_macctrl(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
t_u32 mac_ctrl = 0;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* Sanity tests */
if (argc < 3 || argc > 4) {
printf("Insufficient parameters\n");
printf("mlanutl mlanX macctrl [macctrl]\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: macctrl fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
mac_ctrl = *(t_u32 *)buffer;
if (argc == 3) {
/* GET operation */
printf("MAC Control: 0x%08x\n", mac_ctrl);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process generic commands
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_generic(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], 0, NULL);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if ((ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) < 0) {
perror("mlanutl");
fprintf(stderr, "mlanutl: %s fail\n", argv[2]);
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
if (argc == 3) {
/* GET operation */
printf("%s command response received: %s\n", argv[2], buffer);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Set/Get mlanX FW side MAC address
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_fwmacaddr(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* Sanity tests */
if (argc < 3 || argc > 4) {
printf("Insufficient parameters\n");
printf("mlanutl mlanX fwmacaddr [fwmacaddr]\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: fwmacaddr fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
if (argc == 3) {
/* GET operation */
printf("FW MAC address = ");
print_mac(buffer);
printf("\n");
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
#ifdef RX_PACKET_COALESCE
static void
print_rx_packet_coalesc_help()
{
printf("\nUSAGE: rxpktcoal_cfg [PKT-THRESHOLD] [TIMEOUT]\n\n");
printf("OPTIONS:");
printf("PKT-THRESHOLD: count after which packets would be sent to host. Valid values 1-7\n");
printf("\tTIMEOUT: Time after which packets would be sent to host Valid values 1-4\n");
printf("\tCoalescing is disabled if both or either of PKT-THRESHOLD or TIMEOUT is zero\n\n");
printf("\tEmpty - Get current packet coalescing settings\n");
}
static int
process_rx_pkt_coalesce_cfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
tlvbuf_rx_pkt_coal_t *rx_pkt_info;
int ret = MLAN_STATUS_SUCCESS;
if ((argc != 3) && (argc != 5)) {
printf("ERR:Invalid no. of arguments\n");
print_rx_packet_coalesc_help();
return MLAN_STATUS_FAILURE;
}
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if ((ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) < 0) {
perror("mlanutl");
fprintf(stderr, "mlanutl: %s fail\n", argv[2]);
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (argc == 3) { /* GET operation */
rx_pkt_info = (tlvbuf_rx_pkt_coal_t *)(buffer);
printf("RX packet coalesce configuraion:\n");
printf("Packet threshold=%d\n", rx_pkt_info->rx_pkt_count);
printf("Timeout=%dms\n", rx_pkt_info->delay);
} else {
printf("RX packet coalesce configuration set successfully.\n");
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#endif
/**
* @brief Set/Get mlanX channel time and buffer weight
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_multi_chan_cfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
eth_priv_multi_chan_cfg *multi_chan_info;
MrvlIEtypes_multi_chan_info_t *pmc_info = NULL;
MrvlIEtypes_multi_chan_group_info_t *pmc_grp_info = NULL;
MrvlIEtypesHeader_t *tlv = NULL;
t_u32 interfaces = 0;
t_u16 tlv_type, tlv_len;
int tlv_buf_left = 0, num_intf = 0, bss_type = 0, bss_num = 0;
int ret = MLAN_STATUS_SUCCESS;
if ((argc < 3) || (argc > 4)) {
printf("ERR:Invalid arguments\n");
return MLAN_STATUS_FAILURE;
}
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
prepare_buffer(buffer, argv[2], 0, NULL);
multi_chan_info =
(eth_priv_multi_chan_cfg *)(buffer + strlen(CMD_MARVELL) +
strlen(argv[2]));
if (argc > 3) { /* SET operation */
multi_chan_info->channel_time = atoi(argv[3]);
multi_chan_info->buffer_weight = 1;
}
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if ((ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) < 0) {
perror("mlanutl");
fprintf(stderr, "mlanutl: %s fail\n", argv[2]);
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (argc == 3) { /* GET operation */
multi_chan_info = (eth_priv_multi_chan_cfg *)(buffer);
printf("Channel time = %dus\n", multi_chan_info->channel_time);
printf("Buffer weight = %d\n", multi_chan_info->buffer_weight);
if (multi_chan_info->tlv_len) {
pmc_info =
(MrvlIEtypes_multi_chan_info_t *)
multi_chan_info->tlv_buf;
tlv_buf_left = multi_chan_info->tlv_len;
if (tlv_buf_left < sizeof(MrvlIEtypes_multi_chan_info_t)
|| le16_to_cpu(pmc_info->header.type) !=
MULTI_CHAN_INFO_TLV_ID) {
printf("Invalid TLV in command response!\n");
goto done;
}
tlv_buf_left =
le16_to_cpu(pmc_info->header.len) -
sizeof(pmc_info->status);
printf("Status = %s\n",
le16_to_cpu(pmc_info->
status) ? "Active" : "Inactive");
tlv = (MrvlIEtypesHeader_t *)pmc_info->tlv_buffer;
while (tlv_buf_left >= (int)sizeof(MrvlIEtypesHeader_t)) {
tlv_type = le16_to_cpu(tlv->type);
tlv_len = le16_to_cpu(tlv->len);
if ((sizeof(MrvlIEtypesHeader_t) + tlv_len) >
(unsigned int)tlv_buf_left) {
printf("wrong tlv: tlvLen=%d, tlvBufLeft=%d\n", tlv_len, tlv_buf_left);
break;
}
if (tlv_type != MULTI_CHAN_GROUP_INFO_TLV_ID) {
printf("wrong tlv type:0x%x\n",
tlv_type);
break;
}
pmc_grp_info =
(MrvlIEtypes_multi_chan_group_info_t *)
tlv;
printf("Multi-channel Info: GroupID=%d\n\tChan=%d, Numintf=%d\n", pmc_grp_info->chan_group_id, pmc_grp_info->chan_band_info.chan_num, pmc_grp_info->num_intf);
num_intf = pmc_grp_info->num_intf;
for (interfaces = 0; interfaces < num_intf;
interfaces++) {
bss_type =
pmc_grp_info->
bss_type_numlist[interfaces] >>
4;
bss_num =
pmc_grp_info->
bss_type_numlist[interfaces] &
BSS_NUM_MASK;
printf("\tintf%d: bss_type=%d bss_num=%d\n", interfaces, bss_type, bss_num);
}
tlv_buf_left -=
(sizeof(MrvlIEtypesHeader_t) + tlv_len);
tlv = (MrvlIEtypesHeader_t *)((t_u8 *)tlv +
tlv_len +
sizeof
(MrvlIEtypesHeader_t));
}
}
} else {
printf("Channel time set successfully.\n");
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Set/Get mlanX multi_channel policy
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_multi_chan_policy(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
t_u16 data = 0;
int ret = MLAN_STATUS_SUCCESS;
if ((argc < 3) || (argc > 4)) {
printf("ERR:Invalid arguments\n");
return MLAN_STATUS_FAILURE;
}
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if ((ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) < 0) {
perror("mlanutl");
fprintf(stderr, "mlanutl: %s fail\n", argv[2]);
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (argc == 3) { /* GET operation */
data = *((t_u16 *)buffer);
printf("Multi-Channel Policy: %s\n",
(data) ? "Enabled" : "Disabled");
} else {
printf("Multi-Channel Policy Setting successful!\n");
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Set/Get mlanX drcs time slicing parameters
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_drcs_time_slicing_cfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
eth_priv_drcs_cfg *drcs_cfg;
t_u8 data[8], i;
int ret = MLAN_STATUS_SUCCESS;
if (!((argc == 3) || (argc == 7) || (argc == 11))) {
printf("ERR:Invalid arguments\n");
return MLAN_STATUS_FAILURE;
}
if (argc > 3) {
for (i = 3; i < argc; i++) {
data[i - 3] = a2hex_or_atoi(argv[i]);
}
if (!(data[0] > 0 && data[1] > 0 && data[2] > 0)) {
printf("ERR:Invalid arguments! time should be more than zero !\n");
return MLAN_STATUS_FAILURE;
}
if (data[3] < 0 || data[3] > 0x01) {
printf("ERR:Invalid arguments! Mode only can be set bit0 !\n");
return MLAN_STATUS_FAILURE;
}
/* Set the same parameters for two channels */
if (0x7 == argc) {
if (!(data[2] < data[1])) {
printf("ERR:Invalid arguments! Undozetime should be less than other channel's switchtime!\n");
return MLAN_STATUS_FAILURE;
}
} else {
if (!(data[4] > 0 && data[5] > 0 && data[6] > 0)) {
printf("ERR:Invalid arguments! time should be more than zero !\n");
return MLAN_STATUS_FAILURE;
}
if (!(data[2] < data[5] && data[6] < data[1])) {
printf("ERR:Invalid arguments! Undozetime should be less than other channel's switchtime!\n");
return MLAN_STATUS_FAILURE;
}
if (data[7] < 0 || data[7] > 0x01) {
printf("ERR:Invalid arguments! Mode only can be set bit0 !\n");
return MLAN_STATUS_FAILURE;
}
}
}
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if ((ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) < 0) {
perror("mlanutl");
fprintf(stderr, "mlanutl: %s fail\n", argv[2]);
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (argc == 3) { /* GET operation */
drcs_cfg = (eth_priv_drcs_cfg *) (buffer);
printf("Channel index%d: chantime=%d switchtime=%d undozetime=%d mode=%d\n", (drcs_cfg->chan_idx - 1), drcs_cfg->chantime, drcs_cfg->switchtime, drcs_cfg->undozetime, drcs_cfg->mode);
drcs_cfg++;
printf("Channel index%d: chantime=%d switchtime=%d undozetime=%d mode=%d\n", (drcs_cfg->chan_idx - 1), drcs_cfg->chantime, drcs_cfg->switchtime, drcs_cfg->undozetime, drcs_cfg->mode);
} else {
printf("DRCS parameters are set successfully.\n");
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Process regioncode configuration
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_regioncode(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
t_u32 regioncode;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: regioncode config fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
if (argc == 3) {
memcpy(&regioncode, buffer, sizeof(regioncode));
printf("regioncode: %d\n", regioncode);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process cfpinfo get command
* @param argc Number of arguments
* @param argv Pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_cfpinfo(int argc, char *argv[])
{
t_u8 *data, *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
t_u32 i, size = 0;
t_u32 j;
t_u32 rows, cols;
struct chan_freq_power {
t_u16 channel;
t_u32 freq;
t_u16 max_tx_power;
t_u8 passive_scan_or_radar_detect;
t_u8 flags;
t_u8 blacklist;
} *cfp;
/* Initialize buffer */
buffer = (t_u8 *)malloc(2 * BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = 2 * BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: cfpinfo cmd failed\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
data = buffer;
size = *(t_u32 *)data;
if (!size)
goto out;
/* Region code is stored in first 2 bytes, country code in next 3 bytes
* and environment, if available, in the following byte
*/
data += sizeof(size);
printf("Region Code : 0x%x\n", *(t_u16 *)data);
data += 2;
printf("Country Code : %c%c\n", *data, *(data + 1));
data += 3;
if (size == 6) {
printf("Environment : 0x%x\n", *data);
data++;
}
/* Print cfp tables */
size = *(t_u32 *)data;
if (!size)
goto out;
data += sizeof(size);
printf("\n2.4GHz Channels:\n");
printf("%8s%10s%6s%11s%16s%16s%17s\n", "Channel", "isPassive",
"isDFS", "isDisabled", "is40MHzDisabled",
"is80MHzDisabled", "is160MHzDisabled");
i = 0;
while (i < size) {
if (!(*data))
goto out;
cfp = (struct chan_freq_power *)data;
printf("%8u%10u%6u%11u%16u%16c%17c\n",
cfp->channel,
(cfp->flags & MARVELL_CHANNEL_PASSIVE) ? 1 : 0,
cfp->passive_scan_or_radar_detect,
(cfp->flags & MARVELL_CHANNEL_DISABLED) ? 1 : 0,
(cfp->flags & MARVELL_CHANNEL_NOHT40) ? 1 : 0, '-', '-');
data += sizeof(struct chan_freq_power);
i += sizeof(struct chan_freq_power);
}
size = *(t_u32 *)data;
if (!size)
goto out;
data += sizeof(size);
printf("\n5GHz Channels:\n");
printf("%8s%10s%6s%11s%16s%16s%17s\n", "Channel", "isPassive",
"isDFS", "isDisabled", "is40MHzDisabled",
"is80MHzDisabled", "is160MHzDisabled");
i = 0;
while (i < size) {
if (!(*data))
goto out;
cfp = (struct chan_freq_power *)data;
printf("%8u%10u%6u%11u%16u%16u%17c\n",
cfp->channel,
(cfp->flags & MARVELL_CHANNEL_PASSIVE) ? 1 : 0,
cfp->passive_scan_or_radar_detect,
(cfp->flags & MARVELL_CHANNEL_DISABLED) ? 1 : 0,
(cfp->flags & MARVELL_CHANNEL_NOHT40) ? 1 : 0,
(cfp->flags & MARVELL_CHANNEL_NOHT80) ? 1 : 0, '-');
data += sizeof(struct chan_freq_power);
i += sizeof(struct chan_freq_power);
}
/* Print power tables */
size = *(t_u32 *)data;
if (!size)
goto out;
data += sizeof(size);
rows = *(t_u32 *)data;
data += sizeof(size);
cols = *(t_u32 *)data;
data += sizeof(size);
if (!rows || !cols)
goto out;
printf("\n2.4GHz Power Table:\n");
printf("%8s ", "Channel");
for (i = 0; i < cols - 1; i++)
printf(" m%02d", i);
for (i = 0; i < rows; i++) {
printf("\n%8u ", *data++);
for (j = 1; j < cols; j++)
printf("%3u ", *data++);
}
printf("\n");
size = *(t_u32 *)data;
if (!size)
goto out;
data += sizeof(size);
rows = *(t_u32 *)data;
data += sizeof(size);
cols = *(t_u32 *)data;
data += sizeof(size);
if (!rows || !cols)
goto out;
printf("\n5GHz Power Table:\n");
printf("%8s ", "Channel");
for (i = 0; i < cols - 1; i++)
printf(" m%02d", i);
for (i = 0; i < rows; i++) {
printf("\n%8u ", *data++);
for (j = 1; j < cols; j++)
printf("%3u ", *data++);
}
/* Print Modulation Conversion Information */
printf("\n\nModulation Conversions:\n");
j = 0;
for (i = 0; i < 10; i++)
printf("m%02d: %s\n", j++, mod_conv_bg_1x1[i]);
for (i = 0; i < 6; i++)
printf("m%02d: %s\n", j++, mod_conv_bg_2x2[i]);
if (j >= cols - 1)
goto out;
for (i = 0; i < 6; i++)
printf("m%02d: %s\n", j++, mod_conv_a_1x1[i]);
for (i = 0; i < 6; i++)
printf("m%02d: %s\n", j++, mod_conv_a_2x2[i]);
out:
printf("\n");
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process offchannel configuration
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_offchannel(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* Sanity tests */
if (argc < 3 || argc > 7) {
printf("Incorrect number of parameters\n");
printf("mlanutl mlanX offchannel <action> [<channel> <duration>]\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: offchannel config fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
printf("%s\n", buffer);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process link statistics
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_linkstats(int argc, char *argv[])
{
int ret = MLAN_STATUS_SUCCESS;
t_u8 *buffer = NULL;
t_u8 *data = NULL;
HostCmd_DS_GEN *hostcmd = NULL;
t_u32 cmd_len = 0;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
/* prepare the host cmd */
data = buffer;
prepare_buffer(buffer, HOSTCMD, 0, NULL);
data += strlen(CMD_MARVELL) + strlen(HOSTCMD);
/* add buffer size field */
cmd_len =
sizeof(HostCmd_DS_GEN) + sizeof(HostCmd_DS_LINK_STATS_SUMMARY);
cmd_len = cpu_to_le32(cmd_len);
memcpy(data, &cmd_len, sizeof(t_u32));
data += sizeof(t_u32);
/* add cmd header */
hostcmd = (HostCmd_DS_GEN *)data;
hostcmd->command = cpu_to_le16(HostCmd_CMD_LINK_STATS_SUMMARY);
hostcmd->size = cpu_to_le16(sizeof(HostCmd_DS_GEN));
hostcmd->seq_num = 0;
hostcmd->result = 0;
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: linkstats fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
ret = process_host_cmd_resp(HOSTCMD, buffer);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#if defined(STA_SUPPORT)
/**
* @brief Configure PMF parameters
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_pmfcfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd;
struct eth_priv_pmfcfg pmfcfg;
struct ifreq ifr;
/* Check if arguments are valid */
if ((argc > 5) || (argc == 4) ||
((argc == 5) && ((!atoi(argv[3])) && atoi(argv[4])))) {
printf("ERR: Invalid arguments\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: pmfcfg fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* GET operation */
if (argc == 3) {
memcpy(&pmfcfg, buffer, sizeof(struct eth_priv_pmfcfg));
printf("Management Frame Protection Capability: %s\n",
(pmfcfg.mfpc ? "Yes" : "No"));
if (pmfcfg.mfpc)
printf("Management Frame Protection: %s\n",
(pmfcfg.mfpr ? "Required" : "Optional"));
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
#endif
/**
* @brief Process extended version
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_verext(int argc, char *argv[])
{
int ret = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc < 3 || argc > 4) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX verext [#]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: verext fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
if (cmd->used_len)
printf("Extended Version string received: %s\n", buffer);
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#if defined(STA_SUPPORT) && defined(STA_WEXT)
/**
* @brief Set/Get radio
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_radio_ctrl(int argc, char *argv[])
{
int ret = 0, radio = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc < 3 || argc > 4) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX radioctrl [#]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: radioctrl fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
if (argc == 3) {
memcpy(&radio, buffer, sizeof(radio));
if (radio == 0) {
printf("Radio is Disabled\n");
} else if (radio == 1) {
printf("Radio is Enabled\n");
}
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#endif
/**
* @brief Implement WMM enable command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_wmm_cfg(int argc, char *argv[])
{
int ret = 0, status = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc < 3 || argc > 4) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX wmmcfg [#]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: wmmcfg fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
if (argc == 3) {
memcpy(&status, buffer, sizeof(status));
if (status == 0) {
printf("WMM is Disabled\n");
} else if (status == 1) {
printf("WMM is Enabled\n");
}
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
static int
process_wmm_param_config(int argc, char *argv[])
{
int ret = MLAN_STATUS_SUCCESS;
t_u8 *buffer = NULL;
t_u8 *data = NULL;
HostCmd_DS_GEN *hostcmd = NULL;
t_u32 cmd_len = 0;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
int i = 0;
t_u32 wmm_param[MAX_AC_QUEUES][5];
t_u8 aci = 0;
t_u8 aifsn = 0;
t_u8 ecwmax = 0;
t_u8 ecwmin = 0;
t_u16 txop = 0;
HostCmd_DS_WMM_PARAM_CONFIG *cmd_data = NULL;
/* Sanity tests */
if ((argc < 3) || (argc > (3 + 5 * MAX_AC_QUEUES)) ||
(((argc - 3) % 5) != 0)) {
printf("Incorrect number of parameters\n");
printf("Format reference: mlanutl mlanX wmm_param_config \n");
printf("\t[AC_BE AIFSN ECW_MAX ECW_MIN TX_OP]\n");
printf("\t[AC_BK AIFSN ECW_MAX ECW_MIN TX_OP]\n");
printf("\t[AC_VI AIFSN ECW_MAX ECW_MIN TX_OP]\n");
printf("\t[AC_VO AIFSN ECW_MAX ECW_MIN TX_OP]\n");
return MLAN_STATUS_FAILURE;
}
for (i = 3; i < argc; i++) {
if (IS_HEX_OR_DIGIT(argv[i]) == MLAN_STATUS_FAILURE) {
printf("ERR: Only Number values are allowed\n");
return MLAN_STATUS_FAILURE;
}
}
i = 3;
memset(wmm_param, 0x00, sizeof(wmm_param));
while (i < argc) {
aci = A2HEXDECIMAL(argv[i]);
aifsn = A2HEXDECIMAL(argv[i + 1]);
ecwmax = A2HEXDECIMAL(argv[i + 2]);
ecwmin = A2HEXDECIMAL(argv[i + 3]);
txop = A2HEXDECIMAL(argv[i + 4]);
if ((aci >= 0) && (aci <= 3) && !wmm_param[aci][0]) {
if (((aifsn >= 2) && (aifsn <= 15))
&& ((ecwmax >= 0) && (ecwmax <= 15))
&& ((ecwmin >= 0) && (ecwmin <= 15))
&& ((txop >= 0) && (txop <= 0xFFFF))) {
wmm_param[aci][0] = TRUE;
wmm_param[aci][1] = aifsn;
wmm_param[aci][2] = ecwmax;
wmm_param[aci][3] = ecwmin;
wmm_param[aci][4] = txop;
} else {
printf("wmm parmams invalid\n");
return MLAN_STATUS_FAILURE;
}
} else {
printf("aci out of range or repeated \n");
return MLAN_STATUS_FAILURE;
}
i = i + 5;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
memset(buffer, 0x00, BUFFER_LENGTH);
/* prepare the host cmd */
data = buffer;
prepare_buffer(buffer, HOSTCMD, 0, NULL);
data += strlen(CMD_MARVELL) + strlen(HOSTCMD);
/* add buffer size field */
cmd_len = sizeof(HostCmd_DS_GEN) + sizeof(HostCmd_DS_WMM_PARAM_CONFIG);
cmd_len = cpu_to_le32(cmd_len);
memcpy(data, &cmd_len, sizeof(t_u32));
data += sizeof(t_u32);
/* add cmd header */
hostcmd = (HostCmd_DS_GEN *)data;
hostcmd->command = cpu_to_le16(HostCmd_CMD_WMM_PARAM_CONFIG);
hostcmd->size =
cpu_to_le16(sizeof(HostCmd_DS_GEN) +
sizeof(HostCmd_DS_WMM_PARAM_CONFIG));
hostcmd->seq_num = 0;
hostcmd->result = 0;
data += sizeof(HostCmd_DS_GEN);
cmd_data = (HostCmd_DS_WMM_PARAM_CONFIG *) data;
if (argc > 3) {
cmd_data->action = ACTION_SET;
for (i = 0; i < MAX_AC_QUEUES; i++) {
if (wmm_param[i][0] == TRUE) {
cmd_data->ac_params[i].aci_aifsn.acm = 1;
cmd_data->ac_params[i].aci_aifsn.aci = (t_u8)i;
cmd_data->ac_params[i].aci_aifsn.aifsn =
(t_u8)(wmm_param[i][1]);
cmd_data->ac_params[i].ecw.ecw_max =
(t_u8)(wmm_param[i][2]);
cmd_data->ac_params[i].ecw.ecw_min =
(t_u8)(wmm_param[i][3]);
cmd_data->ac_params[i].tx_op_limit =
cpu_to_le16((t_u16)(wmm_param[i][4]));
}
}
} else
cmd_data->action = ACTION_GET;
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: linkstats fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
ret = process_host_cmd_resp(HOSTCMD, buffer);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#if defined(STA_SUPPORT)
/**
* @brief Implement 802.11D enable command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_11d_cfg(int argc, char *argv[])
{
int ret = 0, status = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc < 3 || argc > 4) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX 11dcfg [#]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: 11dcfg fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
if (argc == 3) {
memcpy(&status, buffer, sizeof(status));
if (status == 0) {
printf("802.11D is Disabled\n");
} else if (status == 1) {
printf("802.11D is Enabled\n");
}
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Implement 802.11D clear chan table command
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_11d_clr_tbl(int argc, char *argv[])
{
int ret = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc != 3) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX 11dclrtbl\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], 0, NULL);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: 11dclrtbl fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#endif
/**
* @brief Set/Get WWS configuration
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_wws_cfg(int argc, char *argv[])
{
int ret = 0, status = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc < 3 || argc > 4) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX wwscfg [#]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: wwscfg fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
if (argc == 3) {
memcpy(&status, buffer, sizeof(status));
if (status == 1) {
printf("WWS is Enabled\n");
} else if (status == 0) {
printf("WWS is Disabled\n");
}
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#if defined(REASSOCIATION)
/**
* @brief Set/Get reassociation settings
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_set_get_reassoc(int argc, char *argv[])
{
int ret = 0, status = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc < 3 || argc > 4) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX reassoctrl [#]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: reassoctrl fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
if (argc == 3) {
memcpy(&status, buffer, sizeof(status));
if (status == 1) {
printf("Re-association is Enabled\n");
} else if (status == 0) {
printf("Re-association is Disabled\n");
}
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#endif
/**
* @brief Get Transmit buffer size
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_txbuf_cfg(int argc, char *argv[])
{
int ret = 0, buf_size = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc != 3) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX txbufcfg\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], 0, NULL);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: txbufcfg fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memcpy(&buf_size, buffer, sizeof(buf_size));
printf("Transmit buffer size is %d\n", buf_size);
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#ifdef STA_SUPPORT
/**
* @brief Set/Get auth type
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_set_get_auth_type(int argc, char *argv[])
{
int ret = 0, auth_type = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc < 3 || argc > 4) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX authtype [#]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: authtype fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
if (argc == 3) {
memcpy(&auth_type, buffer, sizeof(auth_type));
if (auth_type == 1) {
printf("802.11 shared key authentication\n");
} else if (auth_type == 0) {
printf("802.11 open system authentication\n");
} else if (auth_type == 255) {
printf("Allow open system or shared key authentication\n");
}
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#endif
/**
* @brief Set/get user provisioned local power constraint
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_11h_local_pwr_constraint(int argc, char *argv[])
{
int ret = 0, power_cons = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc < 3 || argc > 4) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX powercons [#]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: powercons fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (argc == 3) {
/* Process result */
memcpy(&power_cons, buffer, sizeof(power_cons));
printf("Local power constraint is %d dbm\n", power_cons);
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Set/get HT stream configurations
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_ht_stream_cfg(int argc, char *argv[])
{
int ret = 0, mode = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc < 3 || argc > 4) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX htstreamcfg [#]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: htstreamcfg fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
memcpy(&mode, buffer, sizeof(mode));
if (mode == HT_STREAM_MODE_1X1)
printf("HT stream is in 1x1 mode\n");
else if (mode == HT_STREAM_MODE_2X2)
printf("HT stream is in 2x2 mode\n");
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Set mimo switch configurations
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_mimo_switch(int argc, char *argv[])
{
int ret = 0;
t_u8 *buffer = NULL;
t_u8 tx_antmode = 0, rx_antmode = 0;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc != 5) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX/uapX mimoswitch [txpath_antmode] [rxpath_antmode]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
tx_antmode = (t_u8)a2hex_or_atoi(argv[3]);
rx_antmode = (t_u8)a2hex_or_atoi(argv[4]);
if (!
((tx_antmode == 1 && rx_antmode == 1) ||
(tx_antmode == 2 && rx_antmode == 2) || (rx_antmode == 3 &&
(tx_antmode == 1 ||
tx_antmode == 3)))) {
printf("Error: invalid arguments\n");
printf("The valid values of txpath_antmode and rxpath_antmode are 1/1 2/2 3/3 1/3 \n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: mimoswitch fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
printf("Successfully set Tx path antenna mode: %d, Rx path antenna mode: %d\n", tx_antmode, rx_antmode);
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Get thermal reading
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_thermal(int argc, char *argv[])
{
int ret = 0, thermal = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc != 3) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX thermal\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: thermal fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
memcpy(&thermal, buffer, sizeof(thermal));
printf("Thermal reading is %d\n", thermal);
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#ifdef STA_SUPPORT
/**
* @brief Get signal
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_get_signal(int argc, char *argv[])
{
#define DATA_SIZE 12
int ret = 0, data[DATA_SIZE], i = 0, copy_size = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
memset(data, 0, sizeof(data));
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc < 3 || argc > 5) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX getsignal [m] [n]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: getsignal fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
copy_size = MIN(cmd->used_len, DATA_SIZE * sizeof(int));
memcpy(&data, buffer, copy_size);
printf("Get signal output is\t");
for (i = 0; i < (int)(copy_size / sizeof(int)); i++)
printf("%d\t", data[i]);
printf("\n");
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Set signalext cfg
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_signalext_cfg(int argc, char *argv[])
{
int ret = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc != 4) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX signalextcfg [#]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: signalext cfg fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Get signal
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_get_signal_ext(int argc, char *argv[])
{
#define MAX_NUM_PATH 3
#define PATH_SIZE 13
#define PATH_A 1
#define PATH_B 2
#define PATH_AB 3
int ret = 0, data[PATH_SIZE * MAX_NUM_PATH] = { 0 };
int i = 0, copy_size = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
t_u8 num_path = 0;
memset(data, 0, sizeof(data));
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc != 3 && argc != 4) {
printf("Error: invalid no of arguments\n");
if (strncmp(argv[2], "getsignalextv2", strlen("getsignalextv2"))
== 0)
printf("mlanutl mlanX getsignalextv2 [m]\n");
else if (strncmp
(argv[2], "getsignalext", strlen("getsignalext")) == 0)
printf("mlanutl mlanX getsignalext [m]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: getsignal fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
copy_size = cmd->used_len;
memcpy(&data, (int *)buffer, copy_size);
num_path = copy_size / sizeof(int) / PATH_SIZE;
for (i = 0; i < num_path; i++) {
if (data[i * PATH_SIZE] == PATH_A)
printf("PATH A: %d %d %d %d %d %d %d %d %d %d %d %d\n", data[i * PATH_SIZE + 1], data[i * PATH_SIZE + 2], data[i * PATH_SIZE + 3], data[i * PATH_SIZE + 4], data[i * PATH_SIZE + 5], data[i * PATH_SIZE + 6], data[i * PATH_SIZE + 7], data[i * PATH_SIZE + 8], data[i * PATH_SIZE + 9], data[i * PATH_SIZE + 10], data[i * PATH_SIZE + 11], data[i * PATH_SIZE + 12]);
else if (data[i * PATH_SIZE] == PATH_B)
printf("PATH B: %d %d %d %d %d %d %d %d %d %d %d %d\n", data[i * PATH_SIZE + 1], data[i * PATH_SIZE + 2], data[i * PATH_SIZE + 3], data[i * PATH_SIZE + 4], data[i * PATH_SIZE + 5], data[i * PATH_SIZE + 6], data[i * PATH_SIZE + 7], data[i * PATH_SIZE + 8], data[i * PATH_SIZE + 9], data[i * PATH_SIZE + 10], data[i * PATH_SIZE + 11], data[i * PATH_SIZE + 12]);
else if (data[i * PATH_SIZE] == PATH_AB)
printf("PATH A+B: %d %d %d %d %d %d %d %d %d %d %d %d\n", data[i * PATH_SIZE + 1], data[i * PATH_SIZE + 2], data[i * PATH_SIZE + 3], data[i * PATH_SIZE + 4], data[i * PATH_SIZE + 5], data[i * PATH_SIZE + 6], data[i * PATH_SIZE + 7], data[i * PATH_SIZE + 8], data[i * PATH_SIZE + 9], data[i * PATH_SIZE + 10], data[i * PATH_SIZE + 11], data[i * PATH_SIZE + 12]);
}
printf("\n");
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#endif /* #ifdef STA_SUPPORT */
/**
* @brief Set/Get beacon interval
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_beacon_interval(int argc, char *argv[])
{
int ret = 0, bcninterval = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc < 3 || argc > 4) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX bcninterval [#]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: bcninterval fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
memcpy(&bcninterval, buffer, sizeof(bcninterval));
printf("Beacon interval is %d\n", bcninterval);
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Get/Set inactivity timeout extend
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_inactivity_timeout_ext(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd;
int data[4];
struct ifreq ifr;
/* Check if arguments are valid */
if ((argc != 3) && (argc != 6) && (argc != 7)) {
printf("ERR: Invalid arguments\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: inactivityto fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* GET operation */
if (argc == 3) {
memset(data, 0, sizeof(data));
memcpy(data, buffer, sizeof(data));
printf("Timeout unit is %d us\n"
"Inactivity timeout for unicast data is %d ms\n"
"Inactivity timeout for multicast data is %d ms\n"
"Inactivity timeout for new Rx traffic is %d ms\n",
data[0], data[1], data[2], data[3]);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Enable/Disable amsdu_aggr_ctrl
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_11n_amsdu_aggr_ctrl(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
int ret = 0, data[2];
struct ifreq ifr;
/* Check if arguments are valid */
if ((argc != 3) && (argc != 4)) {
printf("ERR: Invalid arguments\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: amsduaggrctrl fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(data, 0, sizeof(data));
memcpy(data, buffer, sizeof(data));
if (data[0] == 1)
printf("Feature is enabled\n");
if (data[0] == 0)
printf("Feature is disabled\n");
printf("Current AMSDU buffer size is %d\n", data[1]);
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Set/Get Transmit beamforming capabilities
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_tx_bf_cap_ioctl(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
int ret = 0, bf_cap;
struct ifreq ifr;
/* Check if arguments are valid */
if ((argc != 3) && (argc != 4)) {
printf("ERR: Invalid arguments\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: httxbfcap fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memcpy(&bf_cap, buffer, sizeof(int));
printf("Current TX beamforming capability is 0x%x\n", bf_cap);
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Configure sleep parameters
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_sleep_params(int argc, char *argv[])
{
int ret = 0, data[6];
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Check if arguments are valid */
if ((argc != 3) && (argc != 9)) {
printf("ERR: Invalid arguments\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
/* prepare_buffer(buffer, argv[2], 0, NULL); */
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: sleepparams fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(data, 0, sizeof(data));
memcpy(data, buffer, sizeof(data));
printf("Sleep clock error in ppm is %d\n", data[0]);
printf("Wakeup offset in usec is %d\n", data[1]);
printf("Clock stabilization time in usec is %d\n", data[2]);
printf("Control periodic calibration is %d\n", data[3]);
printf("Control the use of external sleep clock is %d\n", data[4]);
printf("Debug is %d\n", data[5]);
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Set/Get cw mode
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_cwmode(int argc, char *argv[])
{
t_u8 *buffer = NULL, *pos = NULL, *action;
char *data = NULL, *args[100];
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
cw_mode_ctrl *cwmode = NULL;
FILE *config_file = NULL;
char *line = NULL;
int li = 0;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
memset(buffer, 0, BUFFER_LENGTH);
pos = buffer;
strncpy((char *)pos, CMD_MARVELL, strlen(CMD_MARVELL));
pos += (strlen(CMD_MARVELL));
strcpy((char *)pos, argv[2]);
pos += (strlen(argv[2]));
action = pos;
pos++;
if (argc > 3) {
*action = 1;
config_file = fopen(argv[3], "r");
if (config_file == NULL) {
perror("CONFIG");
exit(1);
}
line = (char *)malloc(MAX_CONFIG_LINE);
if (!line) {
printf("ERR:Cannot allocate memory for line\n");
exit(1);
}
memset(line, 0, MAX_CONFIG_LINE);
/* Parse file and process */
while (config_get_line
(line, MAX_CONFIG_LINE, config_file, &li, &data)) {
parse_line(line, args);
if (strcmp(args[0], "CW_MODE") == 0)
cwmode = (cw_mode_ctrl *) pos;
else {
if (cwmode) {
if (strcmp(args[0], "Mode") == 0)
cwmode->mode =
a2hex_or_atoi(args[1]);
else if (strcmp(args[0], "Channel") ==
0)
cwmode->channel =
a2hex_or_atoi(args[1]);
else if (strcmp(args[0], "Chaninfo") ==
0)
cwmode->chanInfo =
a2hex_or_atoi(args[1]);
else if (strcmp(args[0], "TxPower") ==
0)
cwmode->txPower =
a2hex_or_atoi(args[1]);
else if (strcmp(args[0], "PktLength") ==
0)
cwmode->pktLength =
a2hex_or_atoi(args[1]);
else if (strcmp(args[0], "RateInfo") ==
0)
cwmode->rateInfo =
a2hex_or_atoi(args[1]);
} else {
printf("invalid config file\n");
printf("Specify the parameters in CW_MODE header as shown below:\n");
printf("CW_MODE = {\n");
printf("//\n");
printf("// specify parameters between CW_MODE header only\n");
printf("//\n");
printf("}\n");
exit(1);
}
}
}
}
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
cmd->buf = buffer;
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: cwmode fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
cwmode = (cw_mode_ctrl *) buffer;
printf("CW Mode:\nMode = %d\nChannel = %d\nChanInfo = 0x%x\n"
"TxPower=%d\nRateInfo=0x%x\nPacket Length=%d\n",
cwmode->mode, cwmode->channel, cwmode->chanInfo,
cwmode->txPower, cwmode->rateInfo, cwmode->pktLength);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Set/Get network monitor configurations
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_net_monitor(int argc, char *argv[])
{
int ret = 0;
int data[5];
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd;
struct ifreq ifr;
/* Check if arguments are valid */
if ((argc != 3) && (argc != 4) && (argc != 7)
&& (argc != 5)
&& (argc != 8)
) {
printf("ERR: Invalid arguments\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: netmon fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(data, 0, sizeof(data));
memcpy(data, buffer, sizeof(data));
printf("Network monitor activity enabled is %d\n", data[0]);
printf("Filter flag is 0x%x\n", data[1]);
/* no need to display channel num and band for disabling
* netmon or if specific channel is not requested
*/
if ((data[0] == 0) || (data[3] == 0)) {
printf("\n");
goto done;
}
printf("802.11 band is %d\n", data[2]);
printf("Channel to monitor is %d\n", data[3]);
printf("Secondary channel bandwidth is %d\n", data[4]);
printf("\n");
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#if defined(DFS_TESTING_SUPPORT)
/**
* @brief Set/Get DFS Testing settings
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_dfs_testing(int argc, char *argv[])
{
int ret = 0, data[4];
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Check if arguments are valid */
if ((argc != 3) && (argc != 7)) {
printf("ERR: Invalid arguments\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: dfstesting fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (argc == 3) {
memset(data, 0, sizeof(data));
memcpy(data, buffer, sizeof(data));
printf("User-configured Channel Availability Check in msec is %d\n", data[0]);
printf("User-configured Non-Occupancy Period in sec is %d\n",
data[1]);
printf("No channel change on radar enabled is %d\n", data[2]);
printf("User-configured channel to change to on radar is %d\n",
data[3]);
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#endif
/**
* @brief Set/Get CFP table codes
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_cfp_code(int argc, char *argv[])
{
int ret = 0, data[2];
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Check if arguments are valid */
if ((argc != 3) && (argc != 4) && (argc != 5)) {
printf("ERR: Invalid arguments\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: cfpcode fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (argc == 3) {
memset(data, 0, sizeof(data));
memcpy(data, buffer, sizeof(data));
printf("Code of the CFP table for 2.4GHz is %d\n", data[0]);
printf("Code of the CFP table for 5GHz is %d\n", data[1]);
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Set/Get Tx/Rx antenna
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_set_get_tx_rx_ant(int argc, char *argv[])
{
int ret = 0;
int data[3] = { 0 };
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Check if arguments are valid */
if ((argc != 3) && (argc != 4)
&& (argc != 5)
) {
printf("ERR: Invalid arguments\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: antcfg fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (argc == 3) {
if (cmd->used_len < sizeof(data)) {
memcpy(data, buffer, cmd->used_len);
printf("Mode of Tx path is %d\n", data[0]);
if (cmd->used_len == (sizeof(int) * 2))
printf("Mode of Rx path is %d\n", data[1]);
} else {
memcpy(data, buffer, sizeof(data));
printf("Mode of Tx/Rx path is %d\n", data[0]);
/* Evaluate time is valid only when SAD is enabled */
if (data[0] == 0xffff) {
printf("Evaluate time = %d\n", data[1]);
/* Current antenna value should be 1,2,3. 0 is invalid value */
if (data[2] > 0)
printf("Current antenna is %d\n",
data[2]);
}
}
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Get/Set system clock
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_sysclock(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd;
int data[65], i = 0;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: sysclock fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* GET operation */
if (argc == 3) {
memset(data, 0, sizeof(data));
memcpy(data, buffer, sizeof(data));
printf("sysclock = ");
for (i = 1; i <= data[0]; i++) {
printf("%d ", data[i]);
}
printf("\n");
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Associate to a specific indexed entry in the ScanTable
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_associate_ssid_bssid(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd;
struct ifreq ifr;
if (argc == 3) {
printf("ERR: Invalid number of arguments\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: associate fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Set/Get Transmit beamforming configuration
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_tx_bf_cfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
char *param = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
t_u32 param_cnt = 0;
int status = MLAN_STATUS_SUCCESS;
int bf_action;
bf_global_cfg *bf_cfg = NULL;
tx_sounding_cfg *tx_snd_cfg = NULL;
if (argc == 3) {
printf("ERR: Invalid number of arguments\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
status = MLAN_STATUS_FAILURE;
goto exit;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: httxbfcfg fail\n");
status = MLAN_STATUS_FAILURE;
goto exit;
}
param = argv[3];
param_cnt = strlen(param);
if (param_cnt == 1) {
/* The first byte represents the beamforming action */
bf_action = atoi(argv[3]);
switch (bf_action) {
case BF_GLOBAL_CONFIGURATION:
bf_cfg = (bf_global_cfg *) buffer;
printf("Action: BF Configuration (%d) \n", bf_action);
printf("Enable: %d\n", bf_cfg->bf_enbl);
printf("Sounding Enable: %d\n",
bf_cfg->sounding_enbl);
printf("Feedback Type: %d\n", bf_cfg->fb_type);
printf("SNR Threshold: %d\n",
bf_cfg->snr_threshold);
printf("Sounding Interval: %d\n",
bf_cfg->sounding_interval);
printf("BF Mode: %d\n", bf_cfg->bf_mode);
break;
case TX_SOUNDING_CFG:
tx_snd_cfg = (tx_sounding_cfg *) buffer;
printf("Action: Tx Sounding (%d) \n", bf_action);
printf("Enable: %d\n",
tx_snd_cfg->tx_sounding_enbl);
printf("Sounding Type: %d\n",
tx_snd_cfg->sounding_type);
printf("Sounding Interval: %d\n",
tx_snd_cfg->sounding_interval);
break;
default:
break;
}
}
exit:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return status;
}
/**
* @brief Control WPS Session Enable/Disable
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_wps_cfg(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd;
struct ifreq ifr;
if (argc < 3 && argc > 4) {
printf("ERR: Invalid number of arguments\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: wpssession fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
printf("%s\n", buffer);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Set/Get Port Control mode
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_port_ctrl(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd;
struct ifreq ifr;
int port_ctrl = 0;
if (argc < 3 && argc > 4) {
printf("ERR: Invalid number of arguments\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: port_ctrl fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (argc == 3) {
port_ctrl = (int)*buffer;
if (port_ctrl == 1)
printf("port_ctrl is Enabled\n");
else
printf("port_ctrl is Disabled\n");
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Private IOCTL entry to get the By-passed TX packet from upper layer
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_bypassed_packet(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: pb_bypass fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/* #ifdef FW_WAKEUP_METHOD */
/**
* @brief Set/Get module configuration
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_fw_wakeup_method(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd;
struct ifreq ifr;
int fw_wakeup_method = 0;
int gpio_pin = 0;
if (argc < 3 || argc > 5) {
printf("ERR: Invalid number of arguments\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: fwwakeupmethod fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (argc == 3) {
fw_wakeup_method = (int)*buffer;
gpio_pin = (int)*(buffer + 4);
if (fw_wakeup_method == 1)
printf("FW wakeup method is interface\n");
else if (fw_wakeup_method == 2)
printf("FW wakeup method is gpio, GPIO Pin is %d\n",
gpio_pin);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/* #endif */
#if defined(WIFI_DIRECT_SUPPORT)
/**
* @brief Set/Get P2P NoA (Notice of Absence) Or OPP-PS parameters
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_cfg_noa_opp_ps(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd;
struct ifreq ifr;
mlan_ds_wifi_direct_config *cfg;
if (argc < 3 || argc > 8) {
printf("ERR: Invalid number of arguments\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: noa_cfg fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (argc == 3) {
cfg = (mlan_ds_wifi_direct_config *)buffer;
if (!cfg) {
printf("Err : Could not get P2P noa configuration\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (cfg->flags & WIFI_DIRECT_NOA) {
printf("noa_enable : %d\n", cfg->noa_enable);
printf("index : %d\n", cfg->index);
printf("noa_count : %d\n", cfg->noa_count);
printf("noa_duration : %d\n", cfg->noa_duration);
printf("noa_interval : %d\n", cfg->noa_interval);
}
if (cfg->flags & WIFI_DIRECT_OPP_PS) {
printf("opp_ps_enable : %d\n", cfg->opp_ps_enable);
printf("ct_window : %d\n", cfg->ct_window);
}
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
#endif
/**
* @brief Issue a dscp map command
*
* @param argc number of arguments
* @param argv A pointer to arguments array
*
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_dscpmap(int argc, char *argv[])
{
int ret = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
unsigned int dscp, tid, idx;
t_u8 dscp_map[64];
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (buffer == NULL) {
fprintf(stderr, "Cannot alloc memory\n");
ret = ENOMEM;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = ENOMEM;
goto done;
}
/* buffer = MRVL_CMD<cmd> */
strncpy((char *)buffer, CMD_MARVELL, strlen(CMD_MARVELL));
strncpy((char *)buffer + strlen(CMD_MARVELL), argv[2], strlen(argv[2]));
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("ioctl[dscpmap]");
printf("ERR:Command sending failed!\n");
ret = -EFAULT;
goto done;
}
memcpy(dscp_map, buffer, sizeof(dscp_map));
if ((argc == 4) && (strcmp(argv[3], "reset") == 0)) {
memset(dscp_map, 0xff, sizeof(dscp_map));
} else if (argc == (3 + sizeof(dscp_map))) {
/* Update the entire dscp table */
for (idx = 3; idx < (3 + sizeof(dscp_map)); idx++) {
tid = a2hex_or_atoi(argv[idx]);
if ((tid >= 0) && (tid < 8)) {
dscp_map[idx - 3] = tid;
}
}
} else if (argc > 3 && argc <= (3 + sizeof(dscp_map))) {
/* Update any dscp entries provided on the command line */
for (idx = 3; idx < argc; idx++) {
if ((sscanf(argv[idx], "%x=%x", &dscp, &tid) == 2)
&& (dscp < sizeof(dscp_map))
&& (tid >= 0)
&& (tid < 8)) {
dscp_map[dscp] = tid;
}
}
} else if (argc != 3) {
printf("Invalid number of arguments\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* buffer = MRVL_CMD<cmd> */
strncpy((char *)buffer, CMD_MARVELL, strlen(CMD_MARVELL));
strncpy((char *)buffer + strlen(CMD_MARVELL), argv[2], strlen(argv[2]));
if (argc > 3)
memcpy(buffer + strlen(CMD_MARVELL) + strlen(argv[2]),
dscp_map, sizeof(dscp_map));
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("ioctl[dscpmap]");
printf("ERR:Command sending failed!\n");
ret = -EFAULT;
goto done;
}
/* Display the active dscp -> TID mapping table */
if (cmd->used_len) {
printf("DscpMap:\n");
hexdump(NULL, buffer, cmd->used_len, ' ');
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Set/Get DF repeater mode parameters
*
* @param argc number of arguments
* @param argv A pointer to arguments array
*
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_dfs_repeater(int argc, char *argv[])
{
int ret = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
dfs_repeater *dfs_rptr = NULL;
if (argc < 3 && argc > 4) {
printf("ERR: Invalid number of arguments\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: %s fail\n", __func__);
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (argc == 3) {
dfs_rptr = (dfs_repeater *) buffer;
printf("DFS repeater mode: %s\n",
(dfs_rptr->mode) ? "On" : "Off");
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#ifdef WIFI_DIRECT_SUPPORT
/**
* @brief Set/Get miracast configuration parameters
*
* @param argc number of arguments
* @param argv A pointer to arguments array
*
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_miracastcfg(int argc, char *argv[])
{
int ret = MLAN_STATUS_SUCCESS;
int data[3];
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
if (argc < 3 && argc > 6) {
fprintf(stderr, "mlanutl: Invalid number of arguments\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
fprintf(stderr, "mlanutl: Cannot allocate memory\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
fprintf(stderr,
"mlanutl: Cannot allocate buffer for command\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: miracastcfg fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(data, 0, sizeof(data));
/* Process result */
memcpy(data, buffer, sizeof(data));
if (argc == 3) {
/* GET operation */
printf("Miracast Configuration:\n");
printf(" Mode: %d\n", data[0]);
printf(" Scan time: %d\n", data[1]);
printf(" Scan channel gap: %d\n", data[2]);
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
#endif /* WIFI_DIRECT_SUPPORT */
/**
* @brief Set/get control to coex RX window size
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_coex_rx_winsize(int argc, char *argv[])
{
int ret = 0;
int coex_rx_winsize = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Check if arguments are valid */
if ((argc != 3) && (argc != 4)) {
printf("ERR: Invalid arguments\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR: Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR: Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: coex_rx_winsize fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (argc == 3) {
memcpy(&coex_rx_winsize, buffer, sizeof(coex_rx_winsize));
printf("COEX RX winsize is %s\n",
coex_rx_winsize ? "enabled" : "disabled");
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
static int
process_txaggrctrl(int argc, char *argv[])
{
int ret = 0;
int txaggrctrl = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Check if arguments are valid */
if ((argc != 3) && (argc != 4)) {
printf("ERR: Invalid arguments\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR: Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR: Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: txaggrctrl fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (argc == 3) {
memcpy(&txaggrctrl, buffer, sizeof(txaggrctrl));
printf("TX AMPDU on infra link is %s\n",
txaggrctrl ? "enabled" : "disabled");
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Set/get control to enable/disable auto TDLS
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_auto_tdls(int argc, char *argv[])
{
int ret = 0;
int autotdls = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Check if arguments are valid */
if ((argc != 3) && (argc != 4)) {
printf("ERR: Invalid arguments\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR: Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR: Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: autotdls fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (argc == 3) {
memcpy(&autotdls, buffer, sizeof(autotdls));
printf("Auto TDLS is %s\n", autotdls ? "enabled" : "disabled");
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Read/Write PCIE register
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_pcie_reg_rw(int argc, char *argv[])
{
int ret = 0, data[2];
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd;
struct ifreq ifr;
/* Check if arguments are valid */
if ((argc != 4) && (argc != 5)) {
printf("ERR: Invalid arguments\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: pcieregrw fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (argc == 4) {
memset(data, 0, sizeof(data));
memcpy(data, buffer, sizeof(data));
printf("Offset of PCIE register is %#x\n", data[0]);
printf("Value at the register is %#x\n", data[1]);
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Read/Write PCIE register/memory from BAR0
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_pcie_bar0_reg_rw(int argc, char *argv[])
{
int ret = 0, data[2];
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd;
struct ifreq ifr;
/* Check if arguments are valid */
if ((argc != 4) && (argc != 5)) {
printf("ERR: Invalid arguments\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: pcieregrw fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (argc == 4) {
memset(data, 0, sizeof(data));
memcpy(data, buffer, sizeof(data));
printf("Offset of PCIE register is %#x\n", data[0]);
printf("Value at the register is %#x\n", data[1]);
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief get SOC sensor temperature.
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_get_sensor_temp(int argc, char *argv[])
{
int ret = 0;
int temp = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc != 3) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX get_sensor_temp\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], 0, NULL);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: temp_sensor fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
memcpy(&temp, buffer, sizeof(t_u32));
printf("SOC temperature is %d C \n", temp);
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Get channel report values
*
* @param chanNum Number of channels
* @param startFreq Start Frequency
* @param duration Duration
* @param pAnpi Pointer to the anpi value
* @param pLoadPercent Pointer to the LoadPercent value
* @param chanWidth Channel width
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
chanrpt_getValues(t_u8 chanNum, t_u16 startFreq,
t_u32 duration, t_s16 *pAnpi, t_u8 *pLoadPercent,
t_u8 chanWidth)
{
int ret = MLAN_STATUS_SUCCESS;
struct ifreq ifr;
t_u8 *buffer = NULL, *pos = NULL;
t_u32 cmd_len = 0, cmd_header_len;
struct eth_priv_cmd *cmd = NULL;
t_u8 *pByte;
int eventLen = 0;
MrvlIEtypes_Data_t *pTlvHdr;
HostCmd_DS_GEN *hostcmd;
HostCmd_DS_CHAN_RPT_RSP *pChanRptRsp = NULL;
HostCmd_DS_CHAN_RPT_REQ *pChanRptReq = NULL;
t_u8 *pChanRptEvent = NULL;
MrvlIEtypes_ChanRptChanLoad_t *pLoadRpt = NULL;
MrvlIEtypes_ChanRptNoiseHist_t *pNoiseRpt = NULL;
cmd_header_len = strlen(CMD_MARVELL) + strlen(HOSTCMD);
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (buffer == NULL) {
fprintf(stderr, "Cannot alloc memory\n");
ret = ENOMEM;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = ENOMEM;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* buffer = MRVL_CMD<cmd> */
strncpy((char *)buffer, CMD_MARVELL, strlen(CMD_MARVELL));
strncpy((char *)buffer + strlen(CMD_MARVELL), HOSTCMD, strlen(HOSTCMD));
/* buffer = MRVL_CMD<cmd><hostcmd_size><HostCmd_DS_GEN><CMD_DS> */
hostcmd = (HostCmd_DS_GEN *)(buffer + cmd_header_len + sizeof(t_u32));
/* Point after host command header */
pos = (t_u8 *)hostcmd + S_DS_GEN;
cmd_len = S_DS_GEN + sizeof(HostCmd_DS_CHAN_RPT_REQ);
hostcmd->command = cpu_to_le16(HostCmd_CMD_CHAN_REPORT_REQUEST);
hostcmd->size = cpu_to_le16(cmd_len);
hostcmd->seq_num = 0;
hostcmd->result = 0;
pChanRptReq = (HostCmd_DS_CHAN_RPT_REQ *)pos;
memset((void *)pChanRptReq, 0x00, sizeof(HostCmd_DS_CHAN_RPT_REQ));
pChanRptReq->chanDesc.chanNum = chanNum;
pChanRptReq->chanDesc.startFreq = cpu_to_le16(startFreq);
pChanRptReq->chanDesc.chanWidth = chanWidth;
pChanRptReq->millisecDwellTime = duration;
/* Put buffer length */
memcpy(buffer + cmd_header_len, &cmd_len, sizeof(t_u32));
/* Initialize the ifr structure */
memset(&ifr, 0, sizeof(ifr));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
/* Perform ioctl */
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("ioctl[chanrpt hostcmd]");
printf("ERR:Command sending failed!\n");
ret = -EFAULT;
goto done;
}
ret = wait_event(EVENT_CHANNEL_REPORT_RDY, &pChanRptEvent, &eventLen);
if (ret || !pChanRptEvent || !eventLen) {
printf("ERR: wait_event failed!\n");
ret = -EFAULT;
goto done;
}
pChanRptRsp = (HostCmd_DS_CHAN_RPT_RSP *)(pChanRptEvent + EVENT_ID_LEN);
eventLen -= EVENT_ID_LEN;
/* TSF is a t_u64, some formatted printing libs have
* trouble printing long longs, so cast and dump as bytes
*/
pByte = (t_u8 *)&pChanRptRsp->startTsf;
pByte = pChanRptRsp->tlvBuffer;
eventLen -= sizeof(pChanRptRsp->commandResult);
eventLen -= sizeof(pChanRptRsp->startTsf);
eventLen -= sizeof(pChanRptRsp->duration);
pByte = pChanRptRsp->tlvBuffer;
while ((unsigned int)eventLen >= sizeof(pTlvHdr->header)) {
pTlvHdr = (MrvlIEtypes_Data_t *)pByte;
pTlvHdr->header.len = le16_to_cpu(pTlvHdr->header.len);
switch (le16_to_cpu(pTlvHdr->header.type)) {
case TLV_TYPE_CHANRPT_CHAN_LOAD:
pLoadRpt = (MrvlIEtypes_ChanRptChanLoad_t *)pTlvHdr;
*pLoadPercent = (pLoadRpt->ccaBusyFraction * 100) / 255;
break;
case TLV_TYPE_CHANRPT_NOISE_HIST:
pNoiseRpt = (MrvlIEtypes_ChanRptNoiseHist_t *)pTlvHdr;
*pAnpi = pNoiseRpt->anpi;
break;
default:
break;
}
pByte += (pTlvHdr->header.len + sizeof(pTlvHdr->header));
eventLen -= (pTlvHdr->header.len + sizeof(pTlvHdr->header));
eventLen = (eventLen > 0) ? eventLen : 0;
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Print x Axis
*
* @param pChanRpt Pointer to the chan report
* @param numChans Number of channels
*
* @return void
*/
static void
chanrpt_print_xAxis(ChanRptInfo_t * pChanRpt, int numChans)
{
int idx;
printf(" `-");
for (idx = 0; idx < numChans; idx++) {
printf("----");
}
printf("\n ");
for (idx = 0; idx < numChans; idx++) {
printf("%03d ", (pChanRpt + idx)->chanNum);
}
printf("\n");
}
/**
* @brief Print anpi
*
* @param pChanRpt Pointer to the chan report
* @param numChans Number of channels
*
* @return void
*/
static void
chanrpt_print_anpi(ChanRptInfo_t * pChanRpt, int numChans)
{
int dumpIdx;
int yAxis;
int yPrint;
printf("\n");
printf(" Average Noise Power Indicator\n");
printf(" -----------------------------\n");
yPrint = 0;
for (yAxis = -55; yAxis >= -95; yAxis -= 2) {
if (yPrint % 2 == 1) {
printf("%2d| ", yAxis);
} else {
printf(" | ");
}
yPrint++;
for (dumpIdx = 0; dumpIdx < numChans; dumpIdx++) {
if ((pChanRpt + dumpIdx)->anpi >= yAxis) {
printf("### ");
} else if ((pChanRpt + dumpIdx)->anpi >= yAxis - 2) {
printf("%3d ", (pChanRpt + dumpIdx)->anpi);
} else {
printf(" ");
}
}
printf("\n");
}
chanrpt_print_xAxis(pChanRpt, numChans);
}
/**
* @brief Print chan load
*
* @param pChanRpt Pointer to the chan report
* @param numChans Number of channels
*
* @return void
*/
static void
chanrpt_print_chanLoad(ChanRptInfo_t * pChanRpt, int numChans)
{
int dumpIdx;
int yAxis;
int yPrint;
printf("\n");
printf(" Channel Load\n");
printf(" ------------\n");
yPrint = 0;
for (yAxis = 100; yAxis >= 0; yAxis -= 5) {
if (yPrint % 2 == 1) {
printf("%2d%%| ", yAxis);
} else {
printf(" | ");
}
yPrint++;
for (dumpIdx = 0; dumpIdx < numChans; dumpIdx++) {
if ((pChanRpt + dumpIdx)->chanLoad >= yAxis) {
printf("### ");
} else if ((pChanRpt + dumpIdx)->chanLoad >= yAxis - 5) {
printf("%2d%% ",
(pChanRpt + dumpIdx)->chanLoad);
} else {
printf(" ");
}
}
printf("\n");
}
chanrpt_print_xAxis(pChanRpt, numChans);
}
/**
* @brief Get chanrpt values and print graph
*
* @param void
*
* @return void
*/
static void
chanrpt_graph(void)
{
int idx;
ChanRptInfo_t chanRpt[14];
memset(chanRpt, 0x00, sizeof(chanRpt));
for (idx = 0; (unsigned int)idx < NELEMENTS(chanRpt); idx++) {
chanRpt[idx].chanNum = idx + 1;
chanrpt_getValues(idx + 1,
0,
100,
&chanRpt[idx].anpi, &chanRpt[idx].chanLoad,
0);
}
chanrpt_print_anpi(chanRpt, NELEMENTS(chanRpt));
chanrpt_print_chanLoad(chanRpt, NELEMENTS(chanRpt));
}
/**
* @brief Loops to get chanrpt values and print graph, at end print 1 average graph
*
* @param loopOnLoad Print Load graph loop on
* @param loopOnAnpi Print anpi graph loop on
* @param loops Loops
*
* @return void
*/
static void
chanrpt_graph_loop(boolean loopOnLoad, boolean loopOnAnpi, int loops)
{
int idx;
int loopsLeft;
ChanRptInfo_t chanRpt[14];
ChanRptInfo_t chanRptAvg[14];
memset(chanRpt, 0x00, sizeof(chanRpt));
memset(chanRptAvg, 0x00, sizeof(chanRptAvg));
for (idx = 0; (unsigned int)idx < NELEMENTS(chanRpt); idx++) {
chanRpt[idx].chanNum = idx + 1;
chanrpt_getValues(idx + 1,
0,
100,
&chanRpt[idx].anpi, &chanRpt[idx].chanLoad,
0);
}
idx = 0;
loopsLeft = loops;
while (loopsLeft) {
chanRpt[idx].chanNum = idx + 1;
chanrpt_getValues(idx + 1,
0,
75,
&chanRpt[idx].anpi, &chanRpt[idx].chanLoad,
0);
chanRptAvg[idx].chanNum = idx + 1;
chanRptAvg[idx].anpi
= (chanRptAvg[idx].anpi * (loops - loopsLeft)
+ chanRpt[idx].anpi) / (loops - loopsLeft + 1);
chanRptAvg[idx].chanLoad
= (chanRptAvg[idx].chanLoad * (loops - loopsLeft)
+ chanRpt[idx].chanLoad) / (loops - loopsLeft + 1);
idx = (idx + 1) % NELEMENTS(chanRpt);
if (idx == 0) {
if (loopOnAnpi) {
chanrpt_print_anpi(chanRpt, NELEMENTS(chanRpt));
}
if (loopOnLoad) {
chanrpt_print_chanLoad(chanRpt,
NELEMENTS(chanRpt));
}
loopsLeft--;
}
}
if (loopOnAnpi) {
chanrpt_print_anpi(chanRptAvg, NELEMENTS(chanRptAvg));
}
if (loopOnLoad) {
chanrpt_print_chanLoad(chanRptAvg, NELEMENTS(chanRptAvg));
}
}
/**
* @brief Issue a changraph command
*
* @param argc number of arguments
* @param argv A pointer to arguments array
*
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_chan_graph(int argc, char *argv[])
{
if (argc == 3) {
chanrpt_graph();
} else if (argc == 5) {
if (strcmp(argv[3], "load") == 0) {
chanrpt_graph_loop(TRUE, FALSE, atoi(argv[4]));
} else if (strcmp(argv[3], "anpi") == 0) {
chanrpt_graph_loop(FALSE, TRUE, atoi(argv[4]));
} else if (strcmp(argv[3], "anpiload") == 0) {
chanrpt_graph_loop(TRUE, TRUE, atoi(argv[4]));
} else {
printf("\nchangraph syntax:"
" changraph <load | anpi | anpiload> <loops>\n\n");
}
}
return MLAN_STATUS_SUCCESS;
}
/**
* @brief enable 11k 1->enable 0->disable
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_11k_cfg(int argc, char *argv[])
{
int ret = 0, status;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc != 3 && argc != 4) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX 11k_enable [0/1]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], argc - 3, &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: 11k_enable fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process Get result */
if (argc == 3) {
memcpy(&status, buffer, sizeof(status));
if (status == 0) {
printf("802.11K is Disabled\n");
} else if (status == 1) {
printf("802.11K is Enabled\n");
}
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief get neighbor list
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
* @Todo: just support get current ESS now.
need add one argu to get specific ESS.
mlanutl mlanX get_nlist SSID
*/
static int
process_11k_neighbor_report(int argc, char *argv[])
{
int ret = 0;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc != 3) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX get_nlist \n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], argc - 3, &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: neighbor_report failed\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process result */
printf("neighbor_report set successfully, please open mlanevent to view nlist result \n");
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Process extended channel switch(ECSA)
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_extend_channel_switch(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: extended channel switch fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Get/Set per packet Txctl and Rxinfo configuration
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_per_pkt_cfg(int argc, char *argv[])
{
int ret = MLAN_STATUS_SUCCESS, i, j;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
MrvlIEtypes_per_pkt_cfg_t *per_pkt_cfg = NULL;
struct ifreq ifr;
t_u8 *pos = NULL;
/* Sanity tests */
if (argc != 3 && argc != 4 && argc < 6) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX perpktcfg [tx_rx_control] [type_num] [ether_type1 ...] [tx_rx_control] [type_num] [ether_type1 ...]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Flag it for our use */
pos = buffer;
strncpy((char *)pos, CMD_MARVELL, strlen(CMD_MARVELL));
pos += (strlen(CMD_MARVELL));
/* Insert command */
strncpy((char *)pos, argv[2], strlen(argv[2]));
pos += (strlen(argv[2]));
if (argc == 3) {
*pos = ACTION_GET;
} else {
*pos = ACTION_SET;
pos++;
i = 3;
while (i < argc) {
per_pkt_cfg = (MrvlIEtypes_per_pkt_cfg_t *) pos;
per_pkt_cfg->header.type = TLV_TYPE_PER_PKT_CFG;
if (a2hex_or_atoi(argv[i]) >= 0 &&
a2hex_or_atoi(argv[i]) <= MAX_TXRX_CTRL) {
per_pkt_cfg->tx_rx_control =
(t_u8)a2hex_or_atoi(argv[i++]);
per_pkt_cfg->header.len += sizeof(t_u8);
if (per_pkt_cfg->tx_rx_control == 0)
break;
else if (i >= argc) {
printf("Error: invalid arguments, type_num is needed when tx_rx_control != 0.\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
} else {
printf("Error: invalid arguments, tx_rx_control <=3\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (a2hex_or_atoi(argv[i]) <= MAX_NUM_ETHER_TYPE &&
a2hex_or_atoi(argv[i]) > 0)
per_pkt_cfg->proto_type_num =
a2hex_or_atoi(argv[i++]);
else {
printf("Error: invalid arguments, type_num <=8\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
for (j = 0; j < per_pkt_cfg->proto_type_num; j++) {
if (i < argc)
per_pkt_cfg->ether_type[j] =
(t_u16)a2hex_or_atoi(argv[i++]);
else {
printf("Error: invalid arguments, number of ether type less than type_num \n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
}
per_pkt_cfg->header.len =
sizeof(MrvlIEtypes_per_pkt_cfg_t) +
per_pkt_cfg->proto_type_num * sizeof(t_u16) -
sizeof(MrvlIEtypesHeader_t);
pos += per_pkt_cfg->header.len +
sizeof(MrvlIEtypesHeader_t);
}
}
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: perpktcfg fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process Get result */
pos = buffer + (strlen(CMD_MARVELL)) + strlen(argv[2]);
if (*pos == ACTION_GET) {
per_pkt_cfg = (MrvlIEtypes_per_pkt_cfg_t *)++ pos;
while (per_pkt_cfg->header.type == TLV_TYPE_PER_PKT_CFG) {
if (per_pkt_cfg->tx_rx_control & TX_PKT_CTRL) {
printf("The ethernet type of per packet Txctrl:\n");
for (j = 0; j < per_pkt_cfg->proto_type_num;
j++) {
printf("0x%04x ",
per_pkt_cfg->ether_type[j]);
}
printf("\n");
} else if (per_pkt_cfg->tx_rx_control & RX_PKT_INFO) {
printf("The ethernet type of per packet Rxinfo:\n");
for (j = 0; j < per_pkt_cfg->proto_type_num;
j++) {
printf("0x%04x ",
per_pkt_cfg->ether_type[j]);
}
printf("\n");
}
pos += per_pkt_cfg->header.len +
sizeof(MrvlIEtypesHeader_t);
per_pkt_cfg = (MrvlIEtypes_per_pkt_cfg_t *) pos;
}
} else if (argc == 4) {
printf("Disable per packet control!\n");
} else {
printf("Successfully do the TXctl/Rxinfo per packet configuration!\n");
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief enable auto_arp 1->enable 0->disable
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_auto_arp(int argc, char *argv[])
{
int ret = 0, status;
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc != 3 && argc != 4) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX auto_arp [0/1]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], argc - 3, &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: auto_arp fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Process Get result */
if (argc == 3) {
memcpy(&status, buffer, sizeof(status));
if (status == 0) {
printf("Auto ARP is Disabled\n");
} else if (status == 1) {
printf("Auto ARP is Enabled\n");
}
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Creates a tx/rx histogram statistic request and send to driver
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_txrxhistogram(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
int ret = MLAN_STATUS_SUCCESS, i;
struct ifreq ifr;
tx_rx_histogram *tx_rx_info;
tx_pkt_rate_info *tx_info;
rx_pkt_rate_info *rx_info;
t_u8 *pos = NULL;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
/* Sanity tests */
if (argc != 5 && argc != 4) {
printf("Error: invalid no of arguments\n");
printf("mlanutl mlanX/uapX txrxhistogram [action: 0/1/2] [tx_rx_statics: 1/2/3]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Insert command */
strncpy((char *)buffer, argv[2], strlen(argv[2]));
tx_rx_info = (tx_rx_histogram *) (buffer + strlen(argv[2]));
tx_rx_info->enable = (t_u8)a2hex_or_atoi(argv[3]);
if (argc == 5 && tx_rx_info->enable == GET_TX_RX_HISTOGRAM)
tx_rx_info->action = (t_u8)a2hex_or_atoi(argv[4]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: get tx/rx histogram fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
pos = buffer + strlen(argv[2]) + 2 * sizeof(t_u8);
if (tx_rx_info->enable & GET_TX_RX_HISTOGRAM) {
if (tx_rx_info->action & FLAG_TX_HISTOGRAM) {
tx_info = (tx_pkt_rate_info *) pos;
printf("The TX histogram statistic:\n");
printf("============================================\n");
for (i = 0; i < 16; i++) {
printf("htmcs_txcnt[%d] = %u\n", i,
tx_info->htmcs_txcnt[i]);
printf("htsgi_txcnt[%d] = %u\n", i,
tx_info->htsgi_txcnt[i]);
printf("htstbcrate_txcnt[%d] = %u\n", i,
tx_info->htstbcrate_txcnt[i]);
}
for (i = 0; i < 10; i++) {
printf("vhtmcs_txcnt[%d] = %u\n", i,
tx_info->vhtmcs_txcnt[i]);
printf("vhtsgi_txcnt[%d] = %u\n", i,
tx_info->vhtsgi_txcnt[i]);
printf("vhtstbcrate_txcnt[%d] = %u\n", i,
tx_info->vhtstbcrate_txcnt[i]);
}
for (i = 0; i < 2; i++)
printf("nss_txcnt[%d] = %u\n", i,
tx_info->nss_txcnt[i]);
for (i = 0; i < 3; i++)
printf("bandwidth_txcnt[%d] = %u\n", i,
tx_info->bandwidth_txcnt[i]);
for (i = 0; i < 4; i++)
printf("preamble_txcnt[%d] = %u\n", i,
tx_info->preamble_txcnt[i]);
printf("ldpc_txcnt = %u\n",
tx_info->ldpc_txcnt);
printf("rts_txcnt = %u\n",
tx_info->rts_txcnt);
printf("ack_RSSI = %d\n\n",
tx_info->ack_RSSI);
pos += sizeof(tx_pkt_rate_info);
}
if (tx_rx_info->action & FLAG_RX_HISTOGRAM) {
rx_info = (rx_pkt_rate_info *) pos;
printf("The RX histogram statistic:\n");
printf("============================================\n");
for (i = 0; i < 16; i++) {
printf("htmcs_rxcnt[%d] = %u\n", i,
rx_info->htmcs_rxcnt[i]);
printf("htsgi_rxcnt[%d] = %u\n", i,
rx_info->htsgi_rxcnt[i]);
printf("htstbcrate_rxcnt[%d] = %u\n", i,
rx_info->htstbcrate_rxcnt[i]);
}
for (i = 0; i < 10; i++) {
printf("vhtmcs_rxcnt[%d] = %u\n", i,
rx_info->vhtmcs_rxcnt[i]);
printf("vhtsgi_rxcnt[%d] = %u\n", i,
rx_info->vhtsgi_rxcnt[i]);
printf("vhtstbcrate_rxcnt[%d] = %u\n", i,
rx_info->vhtstbcrate_rxcnt[i]);
}
for (i = 0; i < 2; i++)
printf("nss_rxcnt[%d] = %u\n", i,
rx_info->nss_rxcnt[i]);
printf("nsts_rxcnt = %u\n",
rx_info->nsts_rxcnt);
for (i = 0; i < 3; i++)
printf("bandwidth_rxcnt[%d] = %u\n", i,
rx_info->bandwidth_rxcnt[i]);
for (i = 0; i < 6; i++)
printf("preamble_rxcnt[%d] = %u\n", i,
rx_info->preamble_rxcnt[i]);
for (i = 0; i < 2; i++)
printf("ldpc_txbfcnt[%d] = %u\n", i,
rx_info->ldpc_txbfcnt[i]);
for (i = 0; i < 2; i++)
printf("rssi_value[%d] = %d\n", i,
rx_info->rssi_value[i]);
for (i = 0; i < 4; i++)
printf("rssi_chain0[%d] = %d\n", i,
rx_info->rssi_chain0[i]);
for (i = 0; i < 4; i++)
printf("rssi_chain1[%d] = %d\n", i,
rx_info->rssi_chain1[i]);
printf("\n");
}
} else if (tx_rx_info->enable & ENABLE_TX_RX_HISTOGRAM)
printf("Enable the TX and RX histogram statistic\n");
else
printf("Disable the TX and RX histogram statistic\n");
if (buffer)
free(buffer);
if (cmd)
free(cmd);
done:
return ret;
}
/**
* @brief Set/Get out band independent reset
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
*/
static int
process_ind_rst_cfg(int argc, char *argv[])
{
int ret = 0;
int data[3] = { 0 };
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Check if arguments are valid */
if ((argc < 3) || (argc > 5)) {
printf("ERR: Invalid arguments\n");
printf("usage: mlanutl <interface> indrstcfg <ir_mode> [gpio_pin]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (((argc == 4) || (argc == 5)) &&
((atoi(argv[3]) < 0) || (atoi(argv[3]) > 2))) {
printf("ERR: Mode must be 0, 1 or 2\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: indrstcfg fail\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
if (argc == 3) {
memcpy(data, buffer, sizeof(data));
/* Display the result */
printf("Independent Reset Mode = %s\n",
(data[0] ==
0) ? "disabled" : ((data[0] ==
1) ? "Out Band" : "In Band"));
if (data[0] == 1)
printf("GPIO Pin = %d\n", data[1]);
}
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
static void
send_dot11_packet(char *ifName, char *file_name)
{
t_u8 sendbuf[BUF_SIZ] = { 0 }, buff[BUF_SIZ] = {
0};
char *args[100], *pos = NULL, mac_addr[20] = { 0 };
struct ether_header *eh = (struct ether_header *)sendbuf;
int data_len = 0, tx_len = 0;
dot11_txcontrol *txc = NULL;
struct sockaddr_ll socket_address;
wsmp_header *header;
t_u8 mac[ETH_ALEN] = { 0 };
FILE *config_file = NULL;
char *line = NULL;
int li = 0, arg_num = 0, ret = 0, i = 0;
int protocol = 0;
int sockfd = 0;
struct ifreq if_idx;
struct ifreq if_mac;
/* Construct the Ethernet header */
memset(sendbuf, 0, BUF_SIZ);
txc = (dot11_txcontrol *) (sendbuf + sizeof(struct ether_header));
config_file = fopen(file_name, "r");
if (config_file == NULL) {
perror("CONFIG");
exit(1);
}
line = (char *)malloc(MAX_CONFIG_LINE);
if (!line) {
printf("ERR:Cannot allocate memory for line\n");
exit(1);
}
memset(line, 0, MAX_CONFIG_LINE);
/* Parse file and process */
while (config_get_line(line, MAX_CONFIG_LINE, config_file, &li, &pos)) {
arg_num = parse_line(line, args);
if (strcmp(args[0], "Datarate") == 0) {
txc->tx_datarate = ((t_u16)A2HEXDECIMAL(args[1]));
printf("datarate(in 0.5Mbps) = %d\n", txc->tx_datarate);
} else if (strcmp(args[0], "Channel") == 0) {
txc->tx_channel = atoi(args[1]);
printf("channel = %d\n", txc->tx_channel);
} else if (strcmp(args[0], "Bandwidth") == 0) {
txc->tx_Bw = (t_u8)A2HEXDECIMAL(args[1]);
printf("Bandwidth = %d\n", txc->tx_Bw);
} else if (strcmp(args[0], "Power") == 0) {
txc->tx_power = (t_u8)A2HEXDECIMAL(args[1]);
printf("powerlevel = %d\n", txc->tx_power);
} else if (strcmp(args[0], "Priority") == 0) {
txc->pkt_priority = atoi(args[1]);
printf("Pkt_priority = %d\n", txc->pkt_priority);
} else if (strcmp(args[0], "Retry_limit") == 0) {
txc->retry_limit = atoi(args[1]);
printf("Retry_limit = %d\n", txc->retry_limit);
} else if (strncmp(args[0], "Addr", 4) == 0) {
strncpy(mac_addr, args[1], 20);
ret = mac2raw(mac_addr, mac);
printf("destination MAC : %s\n", mac_addr);
if (ret != MLAN_STATUS_SUCCESS) {
printf("%s Address \n",
ret ==
MLAN_STATUS_FAILURE ? "Invalid MAC" : ret
==
MAC_BROADCAST ? "Broadcast" :
"Multicast");
}
} else if (strcmp(args[0], "Data") == 0) {
for (i = 0; i < arg_num - 1; i++) {
buff[i] = (t_u8)A2HEXDECIMAL(args[i + 1]);
}
} else if (strcmp(args[0], "Protocol") == 0) {
protocol = A2HEXDECIMAL(args[1]);
printf("protocol = %x\n", protocol);
}
data_len = arg_num - 1;
}
/* Open RAW socket to send/recv on */
if ((sockfd = socket(AF_PACKET, SOCK_RAW, htons(protocol))) == -1) {
perror("socket");
}
/* Get the index of the interface to send on */
memset(&if_idx, 0, sizeof(struct ifreq));
strncpy(if_idx.ifr_name, ifName, IFNAMSIZ - 1);
if (ioctl(sockfd, SIOCGIFINDEX, &if_idx) < 0)
perror("SIOCGIFINDEX");
/*get mac address of the interface */
memset(&if_mac, 0, sizeof(struct ifreq));
strncpy(if_mac.ifr_name, ifName, IFNAMSIZ - 1);
if (ioctl(sockfd, SIOCGIFHWADDR, &if_mac) < 0)
perror("SIOCGIFHWADDR");
memcpy(eh->ether_shost, (u_int8_t *) & if_mac.ifr_hwaddr.sa_data,
MLAN_MAC_ADDR_LENGTH);
/* destination mac address */
for (i = 0; i < MLAN_MAC_ADDR_LENGTH; i++) {
eh->ether_dhost[i] = (uint8_t) mac[i];
}
/* Ethertype field */
eh->ether_type = htons(protocol);
tx_len += sizeof(struct ether_header);
/*Add the length of tx header */
tx_len += sizeof(dot11_txcontrol);
if (protocol == ETH_P_WSMP) {
header = (wsmp_header *) (sendbuf + tx_len);
header->version = 2;
header->sec_type = 5;
header->chan = txc->tx_channel;
header->rate = txc->tx_datarate / 2;
header->tx_pow = txc->tx_power;
header->app_class = 14;
header->acm_len = 0;
header->len = data_len;
tx_len += sizeof(wsmp_header);
}
memcpy(sendbuf + tx_len, buff, data_len);
tx_len += data_len;
/* Index of the network device */
socket_address.sll_ifindex = if_idx.ifr_ifindex;
/* Address length */
socket_address.sll_halen = ETH_ALEN;
memcpy(&socket_address.sll_addr, (uint8_t *) mac, MLAN_MAC_ADDR_LENGTH);
if (sendto(sockfd, sendbuf, tx_len, 0,
(struct sockaddr *)&socket_address,
sizeof(struct sockaddr_ll)) < 0)
perror("Send failed\n");
else
printf("packet sent\n");
}
static void
receive_dot11_packet(char *ifName, int protocol, int verbose)
{
int sockopt, i, j, prev_channel = 0;
t_u8 buf[BUF_SIZ];
ssize_t numbytes;
struct ether_header *eh = (struct ether_header *)buf;
dot11_rxcontrol *rxctrl;
int sockfd = 0;
struct ifreq if_idx;
struct ifreq if_mac;
/* Open RAW socket to recv on */
if ((sockfd = socket(AF_PACKET, SOCK_RAW, htons(protocol))) == -1) {
perror("socket");
}
/* Get the index of the interface to send on */
memset(&if_idx, 0, sizeof(struct ifreq));
strncpy(if_idx.ifr_name, ifName, IFNAMSIZ - 1);
if (ioctl(sockfd, SIOCGIFINDEX, &if_idx) < 0)
perror("SIOCGIFINDEX");
/*get mac address of the interface */
memset(&if_mac, 0, sizeof(struct ifreq));
strncpy(if_mac.ifr_name, ifName, IFNAMSIZ - 1);
if (ioctl(sockfd, SIOCGIFHWADDR, &if_mac) < 0)
perror("SIOCGIFHWADDR");
/* Allow the socket to be reused - incase connection is closed prematurely */
if (setsockopt
(sockfd, SOL_SOCKET, SO_REUSEADDR, &sockopt,
sizeof sockopt) == -1) {
perror("setsockopt");
close(sockfd);
exit(EXIT_FAILURE);
}
/* Bind to device */
if (setsockopt
(sockfd, SOL_SOCKET, SO_BINDTODEVICE, ifName, IFNAMSIZ - 1) == -1) {
perror("SO_BINDTODEVICE");
close(sockfd);
exit(EXIT_FAILURE);
}
printf("protocol type : %x\n", protocol);
printf("waiting to receive data...\n");
rxctrl = (dot11_rxcontrol *) (buf + sizeof(struct ether_header));
while (1) {
numbytes = recvfrom(sockfd, buf, BUF_SIZ, 0, NULL, NULL);
if (verbose == 1) {
printf("\nReceived data from peer - ");
for (i = 0; i < MLAN_MAC_ADDR_LENGTH; i++) {
printf("%02x", eh->ether_shost[i]);
if (i < (MLAN_MAC_ADDR_LENGTH - 1))
printf(":");
}
printf("\n");
printf("\nchannel = %d\ndata rate = %d\n"
"antenna = %d\nRSSI = %d\n",
rxctrl->rx_channel,
rxctrl->rx_datarate,
rxctrl->rx_antenna, rxctrl->rx_RSSI);
i = sizeof(struct ether_header) +
sizeof(dot11_rxcontrol);
if (protocol == ETH_P_WSMP) {
j = i;
printf("WSMP header : \n");
for (; i < j + sizeof(wsmp_header); i++)
printf("%02x ", buf[i]);
printf("\n");
}
printf("Data:\n");
for (; i < numbytes; i++)
printf("%02x ", buf[i]);
printf("\n");
} else {
if (rxctrl->rx_channel != prev_channel) {
printf("channel %d : ", rxctrl->rx_channel);
for (i = 0; i < MLAN_MAC_ADDR_LENGTH; i++)
printf("%x ", eh->ether_shost[i]);
printf("\n");
prev_channel = rxctrl->rx_channel;
} else
printf("*");
fflush(stdout);
}
}
}
/**
* @brief process request to send/recv WSMP packets
*
* @param argc Number of arguments
* @param argv Pointer to the arguments array
*
* @return MLAN_STATUS_SUCCESS/MLAN_STATUS_FAILURE
* */
static int
process_dot11_txrx(int argc, char *argv[])
{
int ret = MLAN_STATUS_SUCCESS;
char ifName[IFNAMSIZ], file_name[100];
int receive_protocol, verbose = 0;
if (argc != 5 && argc != 6) {
fprintf(stderr, "Invalid no. of arguments\n");
fprintf(stderr,
"Usage : ./mlanutil <interface> dot11_txrx <send/recv> <options>\n"
"./mlanutil <interface> dot11_txrx send <config/tx_ctrl.conf>\n"
"./mlanutil <interface> dot11_txrx recv <protocol> [v]\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
/*copy interface name */
strcpy(ifName, argv[1]);
if (!strcmp(argv[3], "send")) {
strcpy(file_name, argv[4]);
if (argc == 5)
send_dot11_packet(ifName, file_name);
else {
fprintf(stderr, "Usage: "
"./mlanutil <interface> dot11_txrx send <config/tx_ctrl.conf>\n");
ret = MLAN_STATUS_FAILURE;
goto done;
}
} else if (!strcmp(argv[3], "recv")) {
receive_protocol = A2HEXDECIMAL(argv[4]);
if (argc == 6 && strcmp(argv[5], "v") == 0)
verbose = 1;
receive_dot11_packet(ifName, receive_protocol, verbose);
} else {
fprintf(stderr, "Invalid option after dot11_txrx\n");
fprintf(stderr,
"Usage : ./mlanutil <interface> dot11_txrx <send/recv> [options]\n"
"./mlanutil <interface> dot11_txrx send <config/tx_ctrl.conf> "
"./mlanutil <interface> dot11_txrx recv <protocol> [v]\n");
}
done:
return ret;
}
/**
* @brief Issue a tsf command
*
* @param argc number of arguments
* @param argv A pointer to arguments array
*
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
int
process_tsf(int argc, char *argv[])
{
int ret = MLAN_STATUS_SUCCESS;
int x;
struct ifreq ifr;
t_u8 *buffer = NULL, *pos = NULL;
t_u32 cmd_len = 0, cmd_header_len;
struct eth_priv_cmd *cmd = NULL;
HostCmd_DS_GEN *hostcmd;
cmd_header_len = strlen(CMD_MARVELL) + strlen(HOSTCMD);
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (buffer == NULL) {
fprintf(stderr, "Cannot alloc memory\n");
ret = ENOMEM;
goto done;
}
memset(buffer, 0, BUFFER_LENGTH);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
ret = ENOMEM;
goto done;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* buffer = MRVL_CMD<cmd> */
strncpy((char *)buffer, CMD_MARVELL, strlen(CMD_MARVELL));
strncpy((char *)buffer + strlen(CMD_MARVELL), HOSTCMD, strlen(HOSTCMD));
/* buffer = MRVL_CMD<cmd><hostcmd_size><HostCmd_DS_GEN><CMD_DS> */
hostcmd = (HostCmd_DS_GEN *)(buffer + cmd_header_len + sizeof(t_u32));
/* Point after host command header */
pos = (t_u8 *)hostcmd + S_DS_GEN;
cmd_len = S_DS_GEN + sizeof(t_u64);
hostcmd->command = cpu_to_le16(HostCmd_CMD_GET_TSF);
hostcmd->size = cpu_to_le16(cmd_len);
hostcmd->seq_num = 0;
hostcmd->result = 0;
/* Put buffer length */
memcpy(buffer + cmd_header_len, &cmd_len, sizeof(t_u32));
/* Initialize the ifr structure */
memset(&ifr, 0, sizeof(ifr));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
/* Perform ioctl */
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("ioctl[hostcmd]");
printf("ERR:Command sending failed!\n");
ret = -EFAULT;
goto done;
}
printf("TSF=");
for (x = 7; x >= 0; x--) {
printf("%02x", pos[x]);
}
puts("\n");
done:
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return ret;
}
/**
* @brief Process dynamic bandwidth set/get
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_dyn_bw(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
int dyn_bw = 0;
/* Check arguments */
if (argc < 3 || argc > 4) {
printf("ERR:Incorrect number of arguments!\n");
printf("Syntax: ./mlanutl mlanX dyn_bw <bw>\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: dyn_bw fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
dyn_bw = *(int *)buffer;
printf("Dynamic bandwidth: %d\n", dyn_bw);
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process tx ampdu protection mode set/get
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_tx_ampdu_prot_mode(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
tx_ampdu_prot_mode_para data;
/* Check arguments */
if (argc < 3 || (argc > 4)) {
printf("ERR:Incorrect number of arguments!\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: tx_ampdu_prot_mode fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
memset((void *)&data, 0, sizeof(data));
memcpy((void *)&data, buffer, sizeof(data));
printf("Tx AMPDU protection mode: ");
if (data.mode == TX_AMPDU_RTS_CTS)
printf("RTS/CTS\n");
else if (data.mode == TX_AMPDU_CTS_2_SELF)
printf("CTS-2-SELF\n");
else
printf("Disabled\n");
printf("\n");
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process set/get deauth control when uap move to another channel
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_ctrldeauth(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: deauthctrl fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process result */
printf("Deauth control: ");
if (buffer[0])
printf("enabled.\n");
else
printf("disabled.\n");
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/**
* @brief Process boot sleep configure command
* @param argc number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
static int
process_bootsleep(int argc, char *argv[])
{
t_u8 *buffer = NULL;
struct eth_priv_cmd *cmd = NULL;
struct ifreq ifr;
/* Check arguments */
if (argc != 3 && argc != 4) {
printf("ERR:Incorrect number of arguments!\n");
printf("Syntax: ./mlanutl mlanX bootsleep <1/0>\n");
return MLAN_STATUS_FAILURE;
}
/* Initialize buffer */
buffer = (t_u8 *)malloc(BUFFER_LENGTH);
if (!buffer) {
printf("ERR:Cannot allocate buffer for command!\n");
return MLAN_STATUS_FAILURE;
}
prepare_buffer(buffer, argv[2], (argc - 3), &argv[3]);
cmd = (struct eth_priv_cmd *)malloc(sizeof(struct eth_priv_cmd));
if (!cmd) {
printf("ERR:Cannot allocate buffer for command!\n");
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Fill up buffer */
#ifdef USERSPACE_32BIT_OVER_KERNEL_64BIT
memset(cmd, 0, sizeof(struct eth_priv_cmd));
memcpy(&cmd->buf, &buffer, sizeof(buffer));
#else
cmd->buf = buffer;
#endif
cmd->used_len = 0;
cmd->total_len = BUFFER_LENGTH;
/* Perform IOCTL */
memset(&ifr, 0, sizeof(struct ifreq));
strncpy(ifr.ifr_ifrn.ifrn_name, dev_name, strlen(dev_name));
ifr.ifr_ifru.ifru_data = (void *)cmd;
if (ioctl(sockfd, MLAN_ETH_PRIV, &ifr)) {
perror("mlanutl");
fprintf(stderr, "mlanutl: bootsleep fail\n");
if (cmd)
free(cmd);
if (buffer)
free(buffer);
return MLAN_STATUS_FAILURE;
}
/* Process Get result */
if (argc == 3) {
printf("boot sleep status: %u\n", *(t_u16 *)buffer);
}
if (buffer)
free(buffer);
if (cmd)
free(cmd);
return MLAN_STATUS_SUCCESS;
}
/********************************************************
Global Functions
********************************************************/
/**
* @brief Entry function for mlanutl
* @param argc Number of arguments
* @param argv A pointer to arguments array
* @return MLAN_STATUS_SUCCESS--success, otherwise--fail
*/
int
main(int argc, char *argv[])
{
int ret = MLAN_STATUS_SUCCESS;
if ((argc == 2) && (strcmp(argv[1], "-v") == 0)) {
fprintf(stdout, "Marvell mlanutl version %s\n", MLANUTL_VER);
exit(0);
}
if (argc < 3) {
fprintf(stderr, "Invalid number of parameters!\n");
display_usage();
exit(1);
}
strncpy(dev_name, argv[1], IFNAMSIZ - 1);
/*
* Create a socket
*/
sockfd = socket(AF_INET, SOCK_STREAM, 0);
if (sockfd < 0) {
fprintf(stderr, "mlanutl: Cannot open socket.\n");
exit(1);
}
ret = process_command(argc, argv);
if (ret == MLAN_STATUS_NOTFOUND) {
ret = process_generic(argc, argv);
if (ret) {
fprintf(stderr, "Invalid command specified!\n");
display_usage();
ret = 1;
}
}
close(sockfd);
return ret;
}