/* $NetBSD: bwi.c,v 1.31.6.2 2017/12/10 10:10:23 snj Exp $ */ /* $OpenBSD: bwi.c,v 1.74 2008/02/25 21:13:30 mglocker Exp $ */ /* * Copyright (c) 2007 The DragonFly Project. All rights reserved. * * This code is derived from software contributed to The DragonFly Project * by Sepherosa Ziehau * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * 3. Neither the name of The DragonFly Project nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific, prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $DragonFly: src/sys/dev/netif/bwi/bwimac.c,v 1.1 2007/09/08 06:15:54 sephe Exp $ */ /* * Broadcom AirForce BCM43xx IEEE 802.11b/g wireless network driver * Generic back end */ /* [TRC: XXX Names beginning with `bwi_ieee80211_*' are those that I think should be in NetBSD's generic 802.11 code, not in this driver.] */ #include __KERNEL_RCSID(0, "$NetBSD: bwi.c,v 1.31.6.2 2017/12/10 10:10:23 snj Exp $"); #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* [TRC: XXX amrr] */ #include #include #include #include #ifdef BWI_DEBUG int bwi_debug = 0; #define DPRINTF(sc, dbg, fmt, ...) \ do { \ if ((sc)->sc_debug & (dbg)) \ aprint_debug_dev((sc)->sc_dev, fmt, ##__VA_ARGS__); \ } while (0) #else /* !BWI_DEBUG */ #define DPRINTF(sc, dbg, fmt, ...) ((void)0) #endif /* BWI_DEBUG */ /* XXX temporary porting goop */ #include #include #include /* XXX does not belong here */ #define IEEE80211_OFDM_PLCP_RATE_MASK 0x0000000f #define IEEE80211_OFDM_PLCP_LEN_MASK 0x0001ffe0 /* * Contention window (slots). [TRC: dfly/net80211/80211.h] */ #define IEEE80211_CW_MAX 1023 /* aCWmax */ #define IEEE80211_CW_MIN_0 31 /* DS/CCK aCWmin, ERP aCWmin(0) */ #define IEEE80211_CW_MIN_1 15 /* OFDM aCWmin, ERP aCWmin(1) */ /* * Slot time (microseconds). [TRC: dfly/net80211/80211.h] */ #define IEEE80211_DUR_SLOT 20 /* DS/CCK slottime, ERP long slottime */ #define IEEE80211_DUR_SHSLOT 9 /* ERP short slottime */ #define IEEE80211_DUR_OFDM_SLOT 9 /* OFDM slottime */ /* XXX end porting goop */ /* MAC */ struct bwi_retry_lim { uint16_t shretry; uint16_t shretry_fb; uint16_t lgretry; uint16_t lgretry_fb; }; struct bwi_clock_freq { uint clkfreq_min; uint clkfreq_max; }; /* XXX does not belong here */ struct ieee80211_ds_plcp_hdr { uint8_t i_signal; uint8_t i_service; uint16_t i_length; uint16_t i_crc; } __packed; static void bwi_sysctlattach(struct bwi_softc *); /* MAC */ static void bwi_tmplt_write_4(struct bwi_mac *, uint32_t, uint32_t); static void bwi_hostflags_write(struct bwi_mac *, uint64_t); static uint64_t bwi_hostflags_read(struct bwi_mac *); static uint16_t bwi_memobj_read_2(struct bwi_mac *, uint16_t, uint16_t); static uint32_t bwi_memobj_read_4(struct bwi_mac *, uint16_t, uint16_t); static void bwi_memobj_write_2(struct bwi_mac *, uint16_t, uint16_t, uint16_t); static void bwi_memobj_write_4(struct bwi_mac *, uint16_t, uint16_t, uint32_t); static int bwi_mac_lateattach(struct bwi_mac *); static int bwi_mac_init(struct bwi_mac *); static void bwi_mac_reset(struct bwi_mac *, int); static void bwi_mac_set_tpctl_11bg(struct bwi_mac *, const struct bwi_tpctl *); static int bwi_mac_test(struct bwi_mac *); static void bwi_mac_setup_tpctl(struct bwi_mac *); static void bwi_mac_dummy_xmit(struct bwi_mac *); static void bwi_mac_init_tpctl_11bg(struct bwi_mac *); static void bwi_mac_detach(struct bwi_mac *); static int bwi_mac_fw_alloc(struct bwi_mac *); static void bwi_mac_fw_free(struct bwi_mac *); static int bwi_mac_fw_image_alloc(struct bwi_mac *, const char *, int idx, struct bwi_fw_image *, uint8_t); static void bwi_mac_fw_image_free(struct bwi_mac *, struct bwi_fw_image *); static int bwi_mac_fw_load(struct bwi_mac *); static int bwi_mac_gpio_init(struct bwi_mac *); static int bwi_mac_gpio_fini(struct bwi_mac *); static int bwi_mac_fw_load_iv(struct bwi_mac *, const struct bwi_fw_image *); static int bwi_mac_fw_init(struct bwi_mac *); static void bwi_mac_opmode_init(struct bwi_mac *); static void bwi_mac_hostflags_init(struct bwi_mac *); static void bwi_mac_bss_param_init(struct bwi_mac *); static void bwi_mac_set_retry_lim(struct bwi_mac *, const struct bwi_retry_lim *); static void bwi_mac_set_ackrates(struct bwi_mac *, const struct ieee80211_rateset *); static int bwi_mac_start(struct bwi_mac *); static int bwi_mac_stop(struct bwi_mac *); static int bwi_mac_config_ps(struct bwi_mac *); static void bwi_mac_reset_hwkeys(struct bwi_mac *); static void bwi_mac_shutdown(struct bwi_mac *); static int bwi_mac_get_property(struct bwi_mac *); static void bwi_mac_updateslot(struct bwi_mac *, int); static int bwi_mac_attach(struct bwi_softc *, int, uint8_t); static void bwi_mac_balance_atten(int *, int *); static void bwi_mac_adjust_tpctl(struct bwi_mac *, int, int); static void bwi_mac_calibrate_txpower(struct bwi_mac *, enum bwi_txpwrcb_type); static void bwi_mac_lock(struct bwi_mac *); static void bwi_mac_unlock(struct bwi_mac *); static void bwi_mac_set_promisc(struct bwi_mac *, int); /* PHY */ static void bwi_phy_write(struct bwi_mac *, uint16_t, uint16_t); static uint16_t bwi_phy_read(struct bwi_mac *, uint16_t); static int bwi_phy_attach(struct bwi_mac *); static void bwi_phy_set_bbp_atten(struct bwi_mac *, uint16_t); static int bwi_phy_calibrate(struct bwi_mac *); static void bwi_tbl_write_2(struct bwi_mac *mac, uint16_t, uint16_t); static void bwi_tbl_write_4(struct bwi_mac *mac, uint16_t, uint32_t); static void bwi_nrssi_write(struct bwi_mac *, uint16_t, int16_t); static int16_t bwi_nrssi_read(struct bwi_mac *, uint16_t); static void bwi_phy_init_11a(struct bwi_mac *); static void bwi_phy_init_11g(struct bwi_mac *); static void bwi_phy_init_11b_rev2(struct bwi_mac *); static void bwi_phy_init_11b_rev4(struct bwi_mac *); static void bwi_phy_init_11b_rev5(struct bwi_mac *); static void bwi_phy_init_11b_rev6(struct bwi_mac *); static void bwi_phy_config_11g(struct bwi_mac *); static void bwi_phy_config_agc(struct bwi_mac *); static void bwi_set_gains(struct bwi_mac *, const struct bwi_gains *); static void bwi_phy_clear_state(struct bwi_phy *); /* RF */ static int16_t bwi_nrssi_11g(struct bwi_mac *); static struct bwi_rf_lo *bwi_get_rf_lo(struct bwi_mac *, uint16_t, uint16_t); static int bwi_rf_lo_isused(struct bwi_mac *, const struct bwi_rf_lo *); static void bwi_rf_write(struct bwi_mac *, uint16_t, uint16_t); static uint16_t bwi_rf_read(struct bwi_mac *, uint16_t); static int bwi_rf_attach(struct bwi_mac *); static void bwi_rf_set_chan(struct bwi_mac *, uint, int); static void bwi_rf_get_gains(struct bwi_mac *); static void bwi_rf_init(struct bwi_mac *); static void bwi_rf_off_11a(struct bwi_mac *); static void bwi_rf_off_11bg(struct bwi_mac *); static void bwi_rf_off_11g_rev5(struct bwi_mac *); static void bwi_rf_workaround(struct bwi_mac *, uint); static struct bwi_rf_lo *bwi_rf_lo_find(struct bwi_mac *, const struct bwi_tpctl *); static void bwi_rf_lo_adjust(struct bwi_mac *, const struct bwi_tpctl *); static void bwi_rf_lo_write(struct bwi_mac *, const struct bwi_rf_lo *); static int bwi_rf_gain_max_reached(struct bwi_mac *, int); static uint16_t bwi_bitswap4(uint16_t); static uint16_t bwi_phy812_value(struct bwi_mac *, uint16_t); static void bwi_rf_init_bcm2050(struct bwi_mac *); static uint16_t bwi_rf_calibval(struct bwi_mac *); static int32_t _bwi_adjust_devide(int32_t, int32_t); static int bwi_rf_calc_txpower(int8_t *, uint8_t, const int16_t[]); static int bwi_rf_map_txpower(struct bwi_mac *); static void bwi_rf_lo_update_11g(struct bwi_mac *); static uint32_t bwi_rf_lo_devi_measure(struct bwi_mac *, uint16_t); static uint16_t bwi_rf_get_tp_ctrl2(struct bwi_mac *); static uint8_t _bwi_rf_lo_update_11g(struct bwi_mac *, uint16_t); static void bwi_rf_lo_measure_11g(struct bwi_mac *, const struct bwi_rf_lo *, struct bwi_rf_lo *, uint8_t); static void bwi_rf_calc_nrssi_slope_11b(struct bwi_mac *); static void bwi_rf_set_nrssi_ofs_11g(struct bwi_mac *); static void bwi_rf_calc_nrssi_slope_11g(struct bwi_mac *); static void bwi_rf_init_sw_nrssi_table(struct bwi_mac *); static void bwi_rf_init_hw_nrssi_table(struct bwi_mac *, uint16_t); static void bwi_rf_set_nrssi_thr_11b(struct bwi_mac *); static int32_t _nrssi_threshold(const struct bwi_rf *, int32_t); static void bwi_rf_set_nrssi_thr_11g(struct bwi_mac *); static void bwi_rf_clear_tssi(struct bwi_mac *); static void bwi_rf_clear_state(struct bwi_rf *); static void bwi_rf_on_11a(struct bwi_mac *); static void bwi_rf_on_11bg(struct bwi_mac *); static void bwi_rf_set_ant_mode(struct bwi_mac *, int); static int bwi_rf_get_latest_tssi(struct bwi_mac *, int8_t[], uint16_t); static int bwi_rf_tssi2dbm(struct bwi_mac *, int8_t, int8_t *); static int bwi_rf_calc_rssi_bcm2050(struct bwi_mac *, const struct bwi_rxbuf_hdr *); static int bwi_rf_calc_rssi_bcm2053(struct bwi_mac *, const struct bwi_rxbuf_hdr *); static int bwi_rf_calc_rssi_bcm2060(struct bwi_mac *, const struct bwi_rxbuf_hdr *); static uint16_t bwi_rf_lo_measure_11b(struct bwi_mac *); static void bwi_rf_lo_update_11b(struct bwi_mac *); /* INTERFACE */ static uint16_t bwi_read_sprom(struct bwi_softc *, uint16_t); static void bwi_setup_desc32(struct bwi_softc *, struct bwi_desc32 *, int, int, bus_addr_t, int, int); static void bwi_power_on(struct bwi_softc *, int); static int bwi_power_off(struct bwi_softc *, int); static int bwi_regwin_switch(struct bwi_softc *, struct bwi_regwin *, struct bwi_regwin **); static int bwi_regwin_select(struct bwi_softc *, int); static void bwi_regwin_info(struct bwi_softc *, uint16_t *, uint8_t *); static void bwi_led_attach(struct bwi_softc *); static void bwi_led_newstate(struct bwi_softc *, enum ieee80211_state); static uint16_t bwi_led_onoff(const struct bwi_led *, uint16_t, int); static void bwi_led_event(struct bwi_softc *, int); static void bwi_led_blink_start(struct bwi_softc *, int, int); static void bwi_led_blink_next(void *); static void bwi_led_blink_end(void *); static int bwi_bbp_attach(struct bwi_softc *); static int bwi_bus_init(struct bwi_softc *, struct bwi_mac *); static void bwi_get_card_flags(struct bwi_softc *); static void bwi_get_eaddr(struct bwi_softc *, uint16_t, uint8_t *); static void bwi_get_clock_freq(struct bwi_softc *, struct bwi_clock_freq *); static int bwi_set_clock_mode(struct bwi_softc *, enum bwi_clock_mode); static int bwi_set_clock_delay(struct bwi_softc *); static int bwi_init(struct ifnet *); static void bwi_init_statechg(struct bwi_softc *, int); static int bwi_ioctl(struct ifnet *, u_long, void *); static void bwi_start(struct ifnet *); static void bwi_watchdog(struct ifnet *); static void bwi_stop(struct ifnet *, int); static void bwi_newstate_begin(struct bwi_softc *, enum ieee80211_state); static int bwi_newstate(struct ieee80211com *, enum ieee80211_state, int); static int bwi_media_change(struct ifnet *); /* [TRC: XXX amrr] */ static void bwi_iter_func(void *, struct ieee80211_node *); static void bwi_amrr_timeout(void *); static void bwi_newassoc(struct ieee80211_node *, int); static struct ieee80211_node * bwi_node_alloc(struct ieee80211_node_table *); static int bwi_dma_alloc(struct bwi_softc *); static void bwi_dma_free(struct bwi_softc *); static void bwi_ring_data_free(struct bwi_ring_data *, struct bwi_softc *); static int bwi_dma_ring_alloc(struct bwi_softc *, struct bwi_ring_data *, bus_size_t, uint32_t); static int bwi_dma_txstats_alloc(struct bwi_softc *, uint32_t, bus_size_t); static void bwi_dma_txstats_free(struct bwi_softc *); static int bwi_dma_mbuf_create(struct bwi_softc *); static void bwi_dma_mbuf_destroy(struct bwi_softc *, int, int); static void bwi_enable_intrs(struct bwi_softc *, uint32_t); static void bwi_disable_intrs(struct bwi_softc *, uint32_t); static int bwi_init_tx_ring32(struct bwi_softc *, int); static void bwi_init_rxdesc_ring32(struct bwi_softc *, uint32_t, bus_addr_t, int, int); static int bwi_init_rx_ring32(struct bwi_softc *); static int bwi_init_txstats32(struct bwi_softc *); static void bwi_setup_rx_desc32(struct bwi_softc *, int, bus_addr_t, int); static void bwi_setup_tx_desc32(struct bwi_softc *, struct bwi_ring_data *, int, bus_addr_t, int); static int bwi_init_tx_ring64(struct bwi_softc *, int); static int bwi_init_rx_ring64(struct bwi_softc *); static int bwi_init_txstats64(struct bwi_softc *); static void bwi_setup_rx_desc64(struct bwi_softc *, int, bus_addr_t, int); static void bwi_setup_tx_desc64(struct bwi_softc *, struct bwi_ring_data *, int, bus_addr_t, int); static int bwi_newbuf(struct bwi_softc *, int, int); static void bwi_set_addr_filter(struct bwi_softc *, uint16_t, const uint8_t *); static int bwi_set_chan(struct bwi_softc *, struct ieee80211_channel *); static void bwi_next_scan(void *); static int bwi_rxeof(struct bwi_softc *, int); static int bwi_rxeof32(struct bwi_softc *); static int bwi_rxeof64(struct bwi_softc *); static void bwi_reset_rx_ring32(struct bwi_softc *, uint32_t); static void bwi_free_txstats32(struct bwi_softc *); static void bwi_free_rx_ring32(struct bwi_softc *); static void bwi_free_tx_ring32(struct bwi_softc *, int); static void bwi_free_txstats64(struct bwi_softc *); static void bwi_free_rx_ring64(struct bwi_softc *); static void bwi_free_tx_ring64(struct bwi_softc *, int); static uint8_t bwi_ieee80211_rate2plcp(uint8_t rate, enum ieee80211_phymode); static uint8_t bwi_ieee80211_plcp2rate(uint8_t rate, enum ieee80211_phymode); static enum bwi_ieee80211_modtype bwi_ieee80211_rate2modtype(uint8_t rate); static uint8_t bwi_ofdm_plcp2rate(const void *); static uint8_t bwi_ds_plcp2rate(const struct ieee80211_ds_plcp_hdr *); static void bwi_ofdm_plcp_header(uint32_t *, int, uint8_t); static void bwi_ds_plcp_header(struct ieee80211_ds_plcp_hdr *, int, uint8_t); static void bwi_plcp_header(void *, int, uint8_t); static int bwi_encap(struct bwi_softc *, int, struct mbuf *, struct ieee80211_node **, int); static void bwi_start_tx32(struct bwi_softc *, uint32_t, int); static void bwi_start_tx64(struct bwi_softc *, uint32_t, int); static void bwi_txeof_status32(struct bwi_softc *); static void bwi_txeof_status64(struct bwi_softc *); static void _bwi_txeof(struct bwi_softc *, uint16_t); static void bwi_txeof_status(struct bwi_softc *, int); static void bwi_txeof(struct bwi_softc *); static int bwi_bbp_power_on(struct bwi_softc *, enum bwi_clock_mode); static void bwi_bbp_power_off(struct bwi_softc *); static int bwi_get_pwron_delay(struct bwi_softc *sc); static int bwi_bus_attach(struct bwi_softc *); static const char *bwi_regwin_name(const struct bwi_regwin *); static int bwi_regwin_is_enabled(struct bwi_softc *, struct bwi_regwin *); static uint32_t bwi_regwin_disable_bits(struct bwi_softc *); static void bwi_regwin_enable(struct bwi_softc *, struct bwi_regwin *, uint32_t); static void bwi_regwin_disable(struct bwi_softc *, struct bwi_regwin *, uint32_t); static void bwi_set_bssid(struct bwi_softc *, const uint8_t *); static void bwi_updateslot(struct ifnet *); static void bwi_calibrate(void *); static int bwi_calc_rssi(struct bwi_softc *, const struct bwi_rxbuf_hdr *); static uint8_t bwi_ieee80211_ack_rate(struct ieee80211_node *, uint8_t); static uint16_t bwi_ieee80211_txtime(struct ieee80211com *, struct ieee80211_node *, uint, uint8_t, uint32_t); /* MAC */ static const uint8_t bwi_sup_macrev[] = { 2, 4, 5, 6, 7, 9, 10, 12 }; /* PHY */ #define SUP_BPHY(num) { .rev = num, .init = bwi_phy_init_11b_rev##num } static const struct { uint8_t rev; void (*init)(struct bwi_mac *); } bwi_sup_bphy[] = { SUP_BPHY(2), SUP_BPHY(4), SUP_BPHY(5), SUP_BPHY(6) }; #undef SUP_BPHY #define BWI_PHYTBL_WRSSI 0x1000 #define BWI_PHYTBL_NOISE_SCALE 0x1400 #define BWI_PHYTBL_NOISE 0x1800 #define BWI_PHYTBL_ROTOR 0x2000 #define BWI_PHYTBL_DELAY 0x2400 #define BWI_PHYTBL_RSSI 0x4000 #define BWI_PHYTBL_SIGMA_SQ 0x5000 #define BWI_PHYTBL_WRSSI_REV1 0x5400 #define BWI_PHYTBL_FREQ 0x5800 static const uint16_t bwi_phy_freq_11g_rev1[] = { BWI_PHY_FREQ_11G_REV1 }; static const uint16_t bwi_phy_noise_11g_rev1[] = { BWI_PHY_NOISE_11G_REV1 }; static const uint16_t bwi_phy_noise_11g[] = { BWI_PHY_NOISE_11G }; static const uint32_t bwi_phy_rotor_11g_rev1[] = { BWI_PHY_ROTOR_11G_REV1 }; static const uint16_t bwi_phy_noise_scale_11g_rev2[] = { BWI_PHY_NOISE_SCALE_11G_REV2 }; static const uint16_t bwi_phy_noise_scale_11g_rev7[] = { BWI_PHY_NOISE_SCALE_11G_REV7 }; static const uint16_t bwi_phy_noise_scale_11g[] = { BWI_PHY_NOISE_SCALE_11G }; static const uint16_t bwi_phy_sigma_sq_11g_rev2[] = { BWI_PHY_SIGMA_SQ_11G_REV2 }; static const uint16_t bwi_phy_sigma_sq_11g_rev7[] = { BWI_PHY_SIGMA_SQ_11G_REV7 }; static const uint32_t bwi_phy_delay_11g_rev1[] = { BWI_PHY_DELAY_11G_REV1 }; /* RF */ #define RF_LO_WRITE(mac, lo) bwi_rf_lo_write((mac), (lo)) #define BWI_RF_2GHZ_CHAN(chan) \ (ieee80211_ieee2mhz((chan), IEEE80211_CHAN_2GHZ) - 2400) #define BWI_DEFAULT_IDLE_TSSI 52 struct rf_saveregs { uint16_t phy_01; uint16_t phy_03; uint16_t phy_0a; uint16_t phy_15; uint16_t phy_2a; uint16_t phy_30; uint16_t phy_35; uint16_t phy_60; uint16_t phy_429; uint16_t phy_802; uint16_t phy_811; uint16_t phy_812; uint16_t phy_814; uint16_t phy_815; uint16_t rf_43; uint16_t rf_52; uint16_t rf_7a; }; #define SAVE_RF_REG(mac, regs, n) (regs)->rf_##n = RF_READ((mac), 0x##n) #define RESTORE_RF_REG(mac, regs, n) RF_WRITE((mac), 0x##n, (regs)->rf_##n) #define SAVE_PHY_REG(mac, regs, n) (regs)->phy_##n = PHY_READ((mac), 0x##n) #define RESTORE_PHY_REG(mac, regs, n) PHY_WRITE((mac), 0x##n, (regs)->phy_##n) static const int8_t bwi_txpower_map_11b[BWI_TSSI_MAX] = { BWI_TXPOWER_MAP_11B }; static const int8_t bwi_txpower_map_11g[BWI_TSSI_MAX] = { BWI_TXPOWER_MAP_11G }; /* INTERFACE */ struct bwi_myaddr_bssid { uint8_t myaddr[IEEE80211_ADDR_LEN]; uint8_t bssid[IEEE80211_ADDR_LEN]; } __packed; /* [TRC: XXX What are these about?] */ #define IEEE80211_DS_PLCP_SERVICE_LOCKED 0x04 #define IEEE80211_DS_PLCL_SERVICE_PBCC 0x08 #define IEEE80211_DS_PLCP_SERVICE_LENEXT5 0x20 #define IEEE80211_DS_PLCP_SERVICE_LENEXT6 0x40 #define IEEE80211_DS_PLCP_SERVICE_LENEXT7 0x80 static const struct { uint16_t did_min; uint16_t did_max; uint16_t bbp_id; } bwi_bbpid_map[] = { { 0x4301, 0x4301, 0x4301 }, { 0x4305, 0x4307, 0x4307 }, { 0x4403, 0x4403, 0x4402 }, { 0x4610, 0x4615, 0x4610 }, { 0x4710, 0x4715, 0x4710 }, { 0x4720, 0x4725, 0x4309 } }; static const struct { uint16_t bbp_id; int nregwin; } bwi_regwin_count[] = { { 0x4301, 5 }, { 0x4306, 6 }, { 0x4307, 5 }, { 0x4310, 8 }, { 0x4401, 3 }, { 0x4402, 3 }, { 0x4610, 9 }, { 0x4704, 9 }, { 0x4710, 9 }, { 0x5365, 7 } }; #define CLKSRC(src) \ [BWI_CLKSRC_ ## src] = { \ .freq_min = BWI_CLKSRC_ ##src## _FMIN, \ .freq_max = BWI_CLKSRC_ ##src## _FMAX \ } static const struct { uint freq_min; uint freq_max; } bwi_clkfreq[BWI_CLKSRC_MAX] = { CLKSRC(LP_OSC), CLKSRC(CS_OSC), CLKSRC(PCI) }; #undef CLKSRC #define VENDOR_LED_ACT(vendor) \ { \ .vid = PCI_VENDOR_##vendor, \ .led_act = { BWI_VENDOR_LED_ACT_##vendor } \ } static const struct { uint16_t vid; uint8_t led_act[BWI_LED_MAX]; } bwi_vendor_led_act[] = { VENDOR_LED_ACT(COMPAQ), VENDOR_LED_ACT(LINKSYS) }; static const uint8_t bwi_default_led_act[BWI_LED_MAX] = { BWI_VENDOR_LED_ACT_DEFAULT }; #undef VENDOR_LED_ACT static const struct { int on_dur; int off_dur; } bwi_led_duration[109] = { [0] = { 400, 100 }, [2] = { 150, 75 }, [4] = { 90, 45 }, [11] = { 66, 34 }, [12] = { 53, 26 }, [18] = { 42, 21 }, [22] = { 35, 17 }, [24] = { 32, 16 }, [36] = { 21, 10 }, [48] = { 16, 8 }, [72] = { 11, 5 }, [96] = { 9, 4 }, [108] = { 7, 3 } }; /* [TRC: XXX Should this be zeroed?] */ static const uint8_t bwi_zero_addr[IEEE80211_ADDR_LEN]; /* [TRC: Derived from DragonFly's src/sys/netproto/802_11/_ieee80211.h */ enum bwi_ieee80211_modtype { IEEE80211_MODTYPE_DS = 0, /* DS/CCK modulation */ IEEE80211_MODTYPE_PBCC = 1, /* PBCC modulation */ IEEE80211_MODTYPE_OFDM = 2 /* OFDM modulation */ }; #define IEEE80211_MODTYPE_CCK IEEE80211_MODTYPE_DS /* * Setup sysctl(3) MIB, hw.bwi.* and hw.bwiN.* */ #ifdef BWI_DEBUG SYSCTL_SETUP(sysctl_bwi, "sysctl bwi(4) subtree setup") { int rc; const struct sysctlnode *rnode; const struct sysctlnode *cnode; if ((rc = sysctl_createv(clog, 0, NULL, &rnode, CTLFLAG_PERMANENT, CTLTYPE_NODE, "bwi", SYSCTL_DESCR("bwi global controls"), NULL, 0, NULL, 0, CTL_HW, CTL_CREATE, CTL_EOL)) != 0) goto err; if ((rc = sysctl_createv(clog, 0, &rnode, &cnode, CTLFLAG_PERMANENT|CTLFLAG_READWRITE, CTLTYPE_INT, "debug", SYSCTL_DESCR("default debug flags"), NULL, 0, &bwi_debug, 0, CTL_CREATE, CTL_EOL)) != 0) goto err; return; err: aprint_error("%s: sysctl_createv failed (rc = %d)\n", __func__, rc); } #endif /* BWI_DEBUG */ static void bwi_sysctlattach(struct bwi_softc *sc) { int rc; const struct sysctlnode *rnode; const struct sysctlnode *cnode; struct sysctllog **clog = &sc->sc_sysctllog; if ((rc = sysctl_createv(clog, 0, NULL, &rnode, CTLFLAG_PERMANENT, CTLTYPE_NODE, device_xname(sc->sc_dev), SYSCTL_DESCR("bwi controls and statistics"), NULL, 0, NULL, 0, CTL_HW, CTL_CREATE, CTL_EOL)) != 0) goto err; if ((rc = sysctl_createv(clog, 0, &rnode, &cnode, CTLFLAG_PERMANENT|CTLFLAG_READWRITE, CTLTYPE_INT, "fw_version", SYSCTL_DESCR("firmware version"), NULL, 0, &sc->sc_fw_version, 0, CTL_CREATE, CTL_EOL)) != 0) goto err; if ((rc = sysctl_createv(clog, 0, &rnode, &cnode, CTLFLAG_PERMANENT|CTLFLAG_READWRITE, CTLTYPE_INT, "dwell_time", SYSCTL_DESCR("channel dwell time during scan (msec)"), NULL, 0, &sc->sc_dwell_time, 0, CTL_CREATE, CTL_EOL)) != 0) goto err; if ((rc = sysctl_createv(clog, 0, &rnode, &cnode, CTLFLAG_PERMANENT|CTLFLAG_READWRITE, CTLTYPE_INT, "led_idle", SYSCTL_DESCR("# ticks before LED enters idle state"), NULL, 0, &sc->sc_led_idle, 0, CTL_CREATE, CTL_EOL)) != 0) goto err; if ((rc = sysctl_createv(clog, 0, &rnode, &cnode, CTLFLAG_PERMANENT|CTLFLAG_READWRITE, CTLTYPE_INT, "led_blink", SYSCTL_DESCR("allow LED to blink"), NULL, 0, &sc->sc_led_blink, 0, CTL_CREATE, CTL_EOL)) != 0) goto err; if ((rc = sysctl_createv(clog, 0, &rnode, &cnode, CTLFLAG_PERMANENT|CTLFLAG_READWRITE, CTLTYPE_INT, "txpwr_calib", SYSCTL_DESCR("enable software TX power calibration"), NULL, 0, &sc->sc_txpwr_calib, 0, CTL_CREATE, CTL_EOL)) != 0) goto err; #ifdef BWI_DEBUG if ((rc = sysctl_createv(clog, 0, &rnode, &cnode, CTLFLAG_PERMANENT|CTLFLAG_READWRITE, CTLTYPE_INT, "debug", SYSCTL_DESCR("debug flags"), NULL, 0, &sc->sc_debug, 0, CTL_CREATE, CTL_EOL)) != 0) goto err; #endif return; err: aprint_error("%s: sysctl_createv failed (rc = %d)\n", __func__, rc); } /* CODE */ int bwi_intr(void *arg) { struct bwi_softc *sc = arg; struct ifnet *ifp = &sc->sc_if; if (!device_is_active(sc->sc_dev) || (ifp->if_flags & IFF_RUNNING) == 0) return (0); /* Disable all interrupts */ bwi_disable_intrs(sc, BWI_ALL_INTRS); softint_schedule(sc->sc_soft_ih); return (1); } static void bwi_softintr(void *arg) { struct bwi_softc *sc = arg; struct bwi_mac *mac; struct ifnet *ifp = &sc->sc_if; uint32_t intr_status; uint32_t txrx_intr_status[BWI_TXRX_NRING]; int i, s, txrx_error, tx = 0, rx_data = -1; if (!device_is_active(sc->sc_dev) || (ifp->if_flags & IFF_RUNNING) == 0) return; for (;;) { /* * Get interrupt status */ intr_status = CSR_READ_4(sc, BWI_MAC_INTR_STATUS); if (intr_status == 0xffffffff) /* Not for us */ goto out; intr_status &= CSR_READ_4(sc, BWI_MAC_INTR_MASK); if (intr_status == 0) /* Nothing is interesting */ goto out; DPRINTF(sc, BWI_DBG_INTR, "intr status 0x%08x\n", intr_status); KASSERT(sc->sc_cur_regwin->rw_type == BWI_REGWIN_T_MAC); mac = (struct bwi_mac *)sc->sc_cur_regwin; txrx_error = 0; for (i = 0; i < BWI_TXRX_NRING; ++i) { uint32_t mask; if (BWI_TXRX_IS_RX(i)) mask = BWI_TXRX_RX_INTRS; else mask = BWI_TXRX_TX_INTRS; txrx_intr_status[i] = CSR_READ_4(sc, BWI_TXRX_INTR_STATUS(i)) & mask; if (txrx_intr_status[i] & BWI_TXRX_INTR_ERROR) { aprint_error_dev(sc->sc_dev, "intr fatal TX/RX (%d) error 0x%08x\n", i, txrx_intr_status[i]); txrx_error = 1; } } /* * Acknowledge interrupt */ CSR_WRITE_4(sc, BWI_MAC_INTR_STATUS, intr_status); for (i = 0; i < BWI_TXRX_NRING; ++i) CSR_WRITE_4(sc, BWI_TXRX_INTR_STATUS(i), txrx_intr_status[i]); if (intr_status & BWI_INTR_PHY_TXERR) { if (mac->mac_flags & BWI_MAC_F_PHYE_RESET) { aprint_error_dev(sc->sc_dev, "intr PHY TX error\n"); /* XXX to netisr0? */ s = splnet(); bwi_init_statechg(sc, 0); splx(s); goto out; } } if (txrx_error) { /* TODO: reset device */ } if (intr_status & BWI_INTR_TBTT) bwi_mac_config_ps(mac); if (intr_status & BWI_INTR_EO_ATIM) aprint_normal_dev(sc->sc_dev, "EO_ATIM\n"); if (intr_status & BWI_INTR_PMQ) { for (;;) { if ((CSR_READ_4(sc, BWI_MAC_PS_STATUS) & 0x8) == 0) break; } CSR_WRITE_2(sc, BWI_MAC_PS_STATUS, 0x2); } if (intr_status & BWI_INTR_NOISE) aprint_normal_dev(sc->sc_dev, "intr noise\n"); if (txrx_intr_status[0] & BWI_TXRX_INTR_RX) rx_data = (sc->sc_rxeof)(sc); if (txrx_intr_status[3] & BWI_TXRX_INTR_RX) { (sc->sc_txeof_status)(sc); tx = 1; } if (intr_status & BWI_INTR_TX_DONE) { bwi_txeof(sc); tx = 1; } if (sc->sc_blink_led != NULL && sc->sc_led_blink) { int evt = BWI_LED_EVENT_NONE; if (tx && rx_data > 0) { if (sc->sc_rx_rate > sc->sc_tx_rate) evt = BWI_LED_EVENT_RX; else evt = BWI_LED_EVENT_TX; } else if (tx) { evt = BWI_LED_EVENT_TX; } else if (rx_data > 0) { evt = BWI_LED_EVENT_RX; } else if (rx_data == 0) { evt = BWI_LED_EVENT_POLL; } if (evt != BWI_LED_EVENT_NONE) bwi_led_event(sc, evt); } } out: /* Re-enable interrupts */ bwi_enable_intrs(sc, BWI_INIT_INTRS); } int bwi_attach(struct bwi_softc *sc) { struct ieee80211com *ic = &sc->sc_ic; struct ifnet *ifp = &sc->sc_if; struct bwi_mac *mac; struct bwi_phy *phy; int s, i, error; /* [TRC: XXX Is this necessary?] */ s = splnet(); sc->sc_soft_ih = softint_establish(SOFTINT_NET, bwi_softintr, sc); if (sc->sc_soft_ih == NULL) { error = ENXIO; goto fail; } /* * Initialize sysctl variables */ sc->sc_fw_version = BWI_FW_VERSION3; sc->sc_dwell_time = 200; sc->sc_led_idle = (2350 * hz) / 1000; sc->sc_led_blink = 1; sc->sc_txpwr_calib = 1; #ifdef BWI_DEBUG sc->sc_debug = bwi_debug; #endif DPRINTF(sc, BWI_DBG_ATTACH, "%s\n", __func__); /* [TRC: XXX amrr] */ /* AMRR rate control */ sc->sc_amrr.amrr_min_success_threshold = 1; sc->sc_amrr.amrr_max_success_threshold = 15; callout_init(&sc->sc_amrr_ch, 0); callout_setfunc(&sc->sc_amrr_ch, bwi_amrr_timeout, sc); callout_init(&sc->sc_scan_ch, 0); callout_setfunc(&sc->sc_scan_ch, bwi_next_scan, sc); callout_init(&sc->sc_calib_ch, 0); callout_setfunc(&sc->sc_calib_ch, bwi_calibrate, sc); bwi_sysctlattach(sc); bwi_power_on(sc, 1); error = bwi_bbp_attach(sc); if (error) goto fail; error = bwi_bbp_power_on(sc, BWI_CLOCK_MODE_FAST); if (error) goto fail; if (BWI_REGWIN_EXIST(&sc->sc_com_regwin)) { error = bwi_set_clock_delay(sc); if (error) goto fail; error = bwi_set_clock_mode(sc, BWI_CLOCK_MODE_FAST); if (error) goto fail; error = bwi_get_pwron_delay(sc); if (error) goto fail; } error = bwi_bus_attach(sc); if (error) goto fail; bwi_get_card_flags(sc); bwi_led_attach(sc); for (i = 0; i < sc->sc_nmac; ++i) { struct bwi_regwin *old; mac = &sc->sc_mac[i]; error = bwi_regwin_switch(sc, &mac->mac_regwin, &old); if (error) goto fail; error = bwi_mac_lateattach(mac); if (error) goto fail; error = bwi_regwin_switch(sc, old, NULL); if (error) goto fail; } /* * XXX First MAC is known to exist * TODO2 */ mac = &sc->sc_mac[0]; phy = &mac->mac_phy; bwi_bbp_power_off(sc); error = bwi_dma_alloc(sc); if (error) goto fail; /* setup interface */ ifp->if_softc = sc; ifp->if_init = bwi_init; ifp->if_ioctl = bwi_ioctl; ifp->if_start = bwi_start; ifp->if_watchdog = bwi_watchdog; ifp->if_stop = bwi_stop; ifp->if_flags = IFF_SIMPLEX | IFF_BROADCAST | IFF_MULTICAST; memcpy(ifp->if_xname, device_xname(sc->sc_dev), IFNAMSIZ); IFQ_SET_READY(&ifp->if_snd); /* Get locale */ sc->sc_locale = __SHIFTOUT(bwi_read_sprom(sc, BWI_SPROM_CARD_INFO), BWI_SPROM_CARD_INFO_LOCALE); DPRINTF(sc, BWI_DBG_ATTACH, "locale: %d\n", sc->sc_locale); /* * Setup ratesets, phytype, channels and get MAC address */ if (phy->phy_mode == IEEE80211_MODE_11B || phy->phy_mode == IEEE80211_MODE_11G) { uint16_t chan_flags; ic->ic_sup_rates[IEEE80211_MODE_11B] = ieee80211_std_rateset_11b; if (phy->phy_mode == IEEE80211_MODE_11B) { chan_flags = IEEE80211_CHAN_B; ic->ic_phytype = IEEE80211_T_DS; } else { chan_flags = IEEE80211_CHAN_CCK | IEEE80211_CHAN_OFDM | IEEE80211_CHAN_DYN | IEEE80211_CHAN_2GHZ; ic->ic_phytype = IEEE80211_T_OFDM; ic->ic_sup_rates[IEEE80211_MODE_11G] = ieee80211_std_rateset_11g; } /* XXX depend on locale */ for (i = 1; i <= 14; ++i) { ic->ic_channels[i].ic_freq = ieee80211_ieee2mhz(i, IEEE80211_CHAN_2GHZ); ic->ic_channels[i].ic_flags = chan_flags; } bwi_get_eaddr(sc, BWI_SPROM_11BG_EADDR, ic->ic_myaddr); if (IEEE80211_IS_MULTICAST(ic->ic_myaddr)) { bwi_get_eaddr(sc, BWI_SPROM_11A_EADDR, ic->ic_myaddr); if (IEEE80211_IS_MULTICAST(ic->ic_myaddr)) aprint_error_dev(sc->sc_dev, "invalid MAC address: %s\n", ether_sprintf(ic->ic_myaddr)); } } else if (phy->phy_mode == IEEE80211_MODE_11A) { /* TODO: 11A */ error = ENXIO; goto fail; } else panic("unknown phymode %d\n", phy->phy_mode); ic->ic_ifp = ifp; ic->ic_caps = IEEE80211_C_SHSLOT | IEEE80211_C_SHPREAMBLE | IEEE80211_C_IBSS | IEEE80211_C_HOSTAP | IEEE80211_C_MONITOR; ic->ic_state = IEEE80211_S_INIT; ic->ic_opmode = IEEE80211_M_STA; ic->ic_updateslot = bwi_updateslot; error = if_initialize(ifp); if (error != 0) { aprint_error_dev(sc->sc_dev, "if_initialize failed(%d)\n", error); goto fail; } ieee80211_ifattach(ic); ifp->if_percpuq = if_percpuq_create(ifp); if_register(ifp); /* [TRC: XXX Not supported on NetBSD?] */ /* ic->ic_flags_ext |= IEEE80211_FEXT_SWBMISS; */ sc->sc_newstate = ic->ic_newstate; ic->ic_newstate = bwi_newstate; /* [TRC: XXX amrr] */ ic->ic_newassoc = bwi_newassoc; ic->ic_node_alloc = bwi_node_alloc; ieee80211_media_init(ic, bwi_media_change, ieee80211_media_status); bpf_attach2(ifp, DLT_IEEE802_11_RADIO, sizeof(struct ieee80211_frame) + IEEE80211_RADIOTAP_HDRLEN, &sc->sc_drvbpf); /* [TRC: XXX DragonFlyBSD rounds this up to a multiple of sizeof(uint32_t). Should we?] */ sc->sc_rxtap_len = sizeof(sc->sc_rxtapu); sc->sc_rxtap.wr_ihdr.it_len = htole16(sc->sc_rxtap_len); sc->sc_rxtap.wr_ihdr.it_present = htole32(BWI_RX_RADIOTAP_PRESENT); sc->sc_txtap_len = sizeof(sc->sc_txtapu); sc->sc_txtap.wt_ihdr.it_len = htole16(sc->sc_txtap_len); sc->sc_txtap.wt_ihdr.it_present = htole32(BWI_TX_RADIOTAP_PRESENT); splx(s); ieee80211_announce(ic); return (0); fail: /* [TRC: XXX DragonFlyBSD detaches the device here. Should we?] */ splx(s); return (error); } void bwi_detach(struct bwi_softc *sc) { struct ifnet *ifp = &sc->sc_if; int i, s; s = splnet(); bwi_stop(ifp, 1); bpf_detach(ifp); ieee80211_ifdetach(&sc->sc_ic); if_detach(ifp); for (i = 0; i < sc->sc_nmac; ++i) bwi_mac_detach(&sc->sc_mac[i]); sysctl_teardown(&sc->sc_sysctllog); if (sc->sc_soft_ih != NULL) softint_disestablish(sc->sc_soft_ih); splx(s); bwi_dma_free(sc); } /* MAC */ static void bwi_tmplt_write_4(struct bwi_mac *mac, uint32_t ofs, uint32_t val) { struct bwi_softc *sc = mac->mac_sc; if (mac->mac_flags & BWI_MAC_F_BSWAP) val = bswap32(val); CSR_WRITE_4(sc, BWI_MAC_TMPLT_CTRL, ofs); CSR_WRITE_4(sc, BWI_MAC_TMPLT_DATA, val); } static void bwi_hostflags_write(struct bwi_mac *mac, uint64_t flags) { uint64_t val; val = flags & 0xffff; MOBJ_WRITE_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_HFLAGS_LO, val); val = (flags >> 16) & 0xffff; MOBJ_WRITE_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_HFLAGS_MI, val); /* HI has unclear meaning, so leave it as it is */ } static uint64_t bwi_hostflags_read(struct bwi_mac *mac) { uint64_t flags, val; /* HI has unclear meaning, so don't touch it */ flags = 0; val = MOBJ_READ_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_HFLAGS_MI); flags |= val << 16; val = MOBJ_READ_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_HFLAGS_LO); flags |= val; return (flags); } static uint16_t bwi_memobj_read_2(struct bwi_mac *mac, uint16_t obj_id, uint16_t ofs0) { struct bwi_softc *sc = mac->mac_sc; uint32_t data_reg; int ofs; data_reg = BWI_MOBJ_DATA; ofs = ofs0 / 4; if (ofs0 % 4 != 0) data_reg = BWI_MOBJ_DATA_UNALIGN; CSR_WRITE_4(sc, BWI_MOBJ_CTRL, BWI_MOBJ_CTRL_VAL(obj_id, ofs)); return (CSR_READ_2(sc, data_reg)); } static uint32_t bwi_memobj_read_4(struct bwi_mac *mac, uint16_t obj_id, uint16_t ofs0) { struct bwi_softc *sc = mac->mac_sc; int ofs; ofs = ofs0 / 4; if (ofs0 % 4 != 0) { uint32_t ret; CSR_WRITE_4(sc, BWI_MOBJ_CTRL, BWI_MOBJ_CTRL_VAL(obj_id, ofs)); ret = CSR_READ_2(sc, BWI_MOBJ_DATA_UNALIGN); ret <<= 16; CSR_WRITE_4(sc, BWI_MOBJ_CTRL, BWI_MOBJ_CTRL_VAL(obj_id, ofs + 1)); ret |= CSR_READ_2(sc, BWI_MOBJ_DATA); return (ret); } else { CSR_WRITE_4(sc, BWI_MOBJ_CTRL, BWI_MOBJ_CTRL_VAL(obj_id, ofs)); return (CSR_READ_4(sc, BWI_MOBJ_DATA)); } } static void bwi_memobj_write_2(struct bwi_mac *mac, uint16_t obj_id, uint16_t ofs0, uint16_t v) { struct bwi_softc *sc = mac->mac_sc; uint32_t data_reg; int ofs; data_reg = BWI_MOBJ_DATA; ofs = ofs0 / 4; if (ofs0 % 4 != 0) data_reg = BWI_MOBJ_DATA_UNALIGN; CSR_WRITE_4(sc, BWI_MOBJ_CTRL, BWI_MOBJ_CTRL_VAL(obj_id, ofs)); CSR_WRITE_2(sc, data_reg, v); } static void bwi_memobj_write_4(struct bwi_mac *mac, uint16_t obj_id, uint16_t ofs0, uint32_t v) { struct bwi_softc *sc = mac->mac_sc; int ofs; ofs = ofs0 / 4; if (ofs0 % 4 != 0) { CSR_WRITE_4(sc, BWI_MOBJ_CTRL, BWI_MOBJ_CTRL_VAL(obj_id, ofs)); CSR_WRITE_2(sc, BWI_MOBJ_DATA_UNALIGN, v >> 16); CSR_WRITE_4(sc, BWI_MOBJ_CTRL, BWI_MOBJ_CTRL_VAL(obj_id, ofs + 1)); CSR_WRITE_2(sc, BWI_MOBJ_DATA, v & 0xffff); } else { CSR_WRITE_4(sc, BWI_MOBJ_CTRL, BWI_MOBJ_CTRL_VAL(obj_id, ofs)); CSR_WRITE_4(sc, BWI_MOBJ_DATA, v); } } static int bwi_mac_lateattach(struct bwi_mac *mac) { int error; if (mac->mac_rev >= 5) CSR_READ_4(mac->mac_sc, BWI_STATE_HI); /* dummy read */ bwi_mac_reset(mac, 1); error = bwi_phy_attach(mac); if (error) return (error); error = bwi_rf_attach(mac); if (error) return (error); /* Link 11B/G PHY, unlink 11A PHY */ if (mac->mac_phy.phy_mode == IEEE80211_MODE_11A) bwi_mac_reset(mac, 0); else bwi_mac_reset(mac, 1); error = bwi_mac_test(mac); if (error) return (error); error = bwi_mac_get_property(mac); if (error) return (error); error = bwi_rf_map_txpower(mac); if (error) return (error); bwi_rf_off(mac); CSR_WRITE_2(mac->mac_sc, BWI_BBP_ATTEN, BWI_BBP_ATTEN_MAGIC); bwi_regwin_disable(mac->mac_sc, &mac->mac_regwin, 0); return (0); } static int bwi_mac_init(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; int error, i; /* Clear MAC/PHY/RF states */ bwi_mac_setup_tpctl(mac); bwi_rf_clear_state(&mac->mac_rf); bwi_phy_clear_state(&mac->mac_phy); /* Enable MAC and linked it to PHY */ if (!bwi_regwin_is_enabled(sc, &mac->mac_regwin)) bwi_mac_reset(mac, 1); /* Initialize backplane */ error = bwi_bus_init(sc, mac); if (error) return (error); /* XXX work around for hardware bugs? */ if (sc->sc_bus_regwin.rw_rev <= 5 && sc->sc_bus_regwin.rw_type != BWI_REGWIN_T_BUSPCIE) { CSR_SETBITS_4(sc, BWI_CONF_LO, __SHIFTIN(BWI_CONF_LO_SERVTO, BWI_CONF_LO_SERVTO_MASK) | __SHIFTIN(BWI_CONF_LO_REQTO, BWI_CONF_LO_REQTO_MASK)); } /* Calibrate PHY */ error = bwi_phy_calibrate(mac); if (error) { aprint_error_dev(sc->sc_dev, "PHY calibrate failed\n"); return (error); } /* Prepare to initialize firmware */ CSR_WRITE_4(sc, BWI_MAC_STATUS, BWI_MAC_STATUS_UCODE_JUMP0 | BWI_MAC_STATUS_IHREN); /* * Load and initialize firmwares */ error = bwi_mac_fw_alloc(mac); if (error) return (error); error = bwi_mac_fw_load(mac); if (error) return (error); error = bwi_mac_gpio_init(mac); if (error) return (error); error = bwi_mac_fw_init(mac); if (error) return (error); /* * Turn on RF */ bwi_rf_on(mac); /* TODO: LED, hardware rf enabled is only related to LED setting */ /* * Initialize PHY */ CSR_WRITE_2(sc, BWI_BBP_ATTEN, 0); bwi_phy_init(mac); /* TODO: interference mitigation */ /* * Setup antenna mode */ bwi_rf_set_ant_mode(mac, mac->mac_rf.rf_ant_mode); /* * Initialize operation mode (RX configuration) */ bwi_mac_opmode_init(mac); /* XXX what's these */ if (mac->mac_rev < 3) { CSR_WRITE_2(sc, 0x60e, 0); CSR_WRITE_2(sc, 0x610, 0x8000); CSR_WRITE_2(sc, 0x604, 0); CSR_WRITE_2(sc, 0x606, 0x200); } else { CSR_WRITE_4(sc, 0x188, 0x80000000); CSR_WRITE_4(sc, 0x18c, 0x2000000); } /* * Initialize TX/RX interrupts' mask */ CSR_WRITE_4(sc, BWI_MAC_INTR_STATUS, BWI_INTR_TIMER1); for (i = 0; i < BWI_TXRX_NRING; ++i) { uint32_t intrs; if (BWI_TXRX_IS_RX(i)) intrs = BWI_TXRX_RX_INTRS; else intrs = BWI_TXRX_TX_INTRS; CSR_WRITE_4(sc, BWI_TXRX_INTR_MASK(i), intrs); } /* XXX what's this */ CSR_SETBITS_4(sc, BWI_STATE_LO, 0x100000); /* Setup MAC power up delay */ CSR_WRITE_2(sc, BWI_MAC_POWERUP_DELAY, sc->sc_pwron_delay); /* Set MAC regwin revision */ MOBJ_WRITE_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_MACREV, mac->mac_rev); /* * Initialize host flags */ bwi_mac_hostflags_init(mac); /* * Initialize BSS parameters */ bwi_mac_bss_param_init(mac); /* * Initialize TX rings */ for (i = 0; i < BWI_TX_NRING; ++i) { error = (sc->sc_init_tx_ring)(sc, i); if (error) { aprint_error_dev(sc->sc_dev, "can't initialize %dth TX ring\n", i); return (error); } } /* * Initialize RX ring */ error = (sc->sc_init_rx_ring)(sc); if (error) { aprint_error_dev(sc->sc_dev, "can't initialize RX ring\n"); return (error); } /* * Initialize TX stats if the current MAC uses that */ if (mac->mac_flags & BWI_MAC_F_HAS_TXSTATS) { error = (sc->sc_init_txstats)(sc); if (error) { aprint_error_dev(sc->sc_dev, "can't initialize TX stats ring\n"); return (error); } } /* XXX what's these */ CSR_WRITE_2(sc, 0x612, 0x50); /* Force Pre-TBTT to 80? */ MOBJ_WRITE_2(mac, BWI_COMM_MOBJ, 0x416, 0x50); MOBJ_WRITE_2(mac, BWI_COMM_MOBJ, 0x414, 0x1f4); mac->mac_flags |= BWI_MAC_F_INITED; return (0); } static void bwi_mac_reset(struct bwi_mac *mac, int link_phy) { struct bwi_softc *sc = mac->mac_sc; uint32_t flags, state_lo, status; flags = BWI_STATE_LO_FLAG_PHYRST | BWI_STATE_LO_FLAG_PHYCLKEN; if (link_phy) flags |= BWI_STATE_LO_FLAG_PHYLNK; bwi_regwin_enable(sc, &mac->mac_regwin, flags); DELAY(2000); state_lo = CSR_READ_4(sc, BWI_STATE_LO); state_lo |= BWI_STATE_LO_GATED_CLOCK; state_lo &= ~__SHIFTIN(BWI_STATE_LO_FLAG_PHYRST, BWI_STATE_LO_FLAGS_MASK); CSR_WRITE_4(sc, BWI_STATE_LO, state_lo); /* Flush pending bus write */ CSR_READ_4(sc, BWI_STATE_LO); DELAY(1000); state_lo &= ~BWI_STATE_LO_GATED_CLOCK; CSR_WRITE_4(sc, BWI_STATE_LO, state_lo); /* Flush pending bus write */ CSR_READ_4(sc, BWI_STATE_LO); DELAY(1000); CSR_WRITE_2(sc, BWI_BBP_ATTEN, 0); status = CSR_READ_4(sc, BWI_MAC_STATUS); status |= BWI_MAC_STATUS_IHREN; if (link_phy) status |= BWI_MAC_STATUS_PHYLNK; else status &= ~BWI_MAC_STATUS_PHYLNK; CSR_WRITE_4(sc, BWI_MAC_STATUS, status); if (link_phy) { DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_ATTACH | BWI_DBG_INIT, "%s\n", "PHY is linked"); mac->mac_phy.phy_flags |= BWI_PHY_F_LINKED; } else { DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_ATTACH | BWI_DBG_INIT, "%s\n", "PHY is unlinked"); mac->mac_phy.phy_flags &= ~BWI_PHY_F_LINKED; } } static void bwi_mac_set_tpctl_11bg(struct bwi_mac *mac, const struct bwi_tpctl *new_tpctl) { struct bwi_rf *rf = &mac->mac_rf; struct bwi_tpctl *tpctl = &mac->mac_tpctl; if (new_tpctl != NULL) { KASSERT(new_tpctl->bbp_atten <= BWI_BBP_ATTEN_MAX); KASSERT(new_tpctl->rf_atten <= (rf->rf_rev < 6 ? BWI_RF_ATTEN_MAX0 : BWI_RF_ATTEN_MAX1)); KASSERT(new_tpctl->tp_ctrl1 <= BWI_TPCTL1_MAX); tpctl->bbp_atten = new_tpctl->bbp_atten; tpctl->rf_atten = new_tpctl->rf_atten; tpctl->tp_ctrl1 = new_tpctl->tp_ctrl1; } /* Set BBP attenuation */ bwi_phy_set_bbp_atten(mac, tpctl->bbp_atten); /* Set RF attenuation */ RF_WRITE(mac, BWI_RFR_ATTEN, tpctl->rf_atten); MOBJ_WRITE_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_RF_ATTEN, tpctl->rf_atten); /* Set TX power */ if (rf->rf_type == BWI_RF_T_BCM2050) { RF_FILT_SETBITS(mac, BWI_RFR_TXPWR, ~BWI_RFR_TXPWR1_MASK, __SHIFTIN(tpctl->tp_ctrl1, BWI_RFR_TXPWR1_MASK)); } /* Adjust RF Local Oscillator */ if (mac->mac_phy.phy_mode == IEEE80211_MODE_11G) bwi_rf_lo_adjust(mac, tpctl); } static int bwi_mac_test(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; uint32_t orig_val, val; #define TEST_VAL1 0xaa5555aa #define TEST_VAL2 0x55aaaa55 /* Save it for later restoring */ orig_val = MOBJ_READ_4(mac, BWI_COMM_MOBJ, 0); /* Test 1 */ MOBJ_WRITE_4(mac, BWI_COMM_MOBJ, 0, TEST_VAL1); val = MOBJ_READ_4(mac, BWI_COMM_MOBJ, 0); if (val != TEST_VAL1) { aprint_error_dev(sc->sc_dev, "TEST1 failed\n"); return (ENXIO); } /* Test 2 */ MOBJ_WRITE_4(mac, BWI_COMM_MOBJ, 0, TEST_VAL2); val = MOBJ_READ_4(mac, BWI_COMM_MOBJ, 0); if (val != TEST_VAL2) { aprint_error_dev(sc->sc_dev, "TEST2 failed\n"); return (ENXIO); } /* Restore to the original value */ MOBJ_WRITE_4(mac, BWI_COMM_MOBJ, 0, orig_val); val = CSR_READ_4(sc, BWI_MAC_STATUS); if ((val & ~BWI_MAC_STATUS_PHYLNK) != BWI_MAC_STATUS_IHREN) { aprint_error_dev(sc->sc_dev, "%s failed, MAC status 0x%08x\n", __func__, val); return (ENXIO); } val = CSR_READ_4(sc, BWI_MAC_INTR_STATUS); if (val != 0) { aprint_error_dev(sc->sc_dev, "%s failed, intr status %08x\n", __func__, val); return (ENXIO); } #undef TEST_VAL2 #undef TEST_VAL1 return (0); } static void bwi_mac_setup_tpctl(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct bwi_rf *rf = &mac->mac_rf; struct bwi_phy *phy = &mac->mac_phy; struct bwi_tpctl *tpctl = &mac->mac_tpctl; /* Calc BBP attenuation */ if (rf->rf_type == BWI_RF_T_BCM2050 && rf->rf_rev < 6) tpctl->bbp_atten = 0; else tpctl->bbp_atten = 2; /* Calc TX power CTRL1?? */ tpctl->tp_ctrl1 = 0; if (rf->rf_type == BWI_RF_T_BCM2050) { if (rf->rf_rev == 1) tpctl->tp_ctrl1 = 3; else if (rf->rf_rev < 6) tpctl->tp_ctrl1 = 2; else if (rf->rf_rev == 8) tpctl->tp_ctrl1 = 1; } /* Empty TX power CTRL2?? */ tpctl->tp_ctrl2 = 0xffff; /* * Calc RF attenuation */ if (phy->phy_mode == IEEE80211_MODE_11A) { tpctl->rf_atten = 0x60; goto back; } if (BWI_IS_BRCM_BCM4309G(sc) && sc->sc_pci_revid < 0x51) { tpctl->rf_atten = sc->sc_pci_revid < 0x43 ? 2 : 3; goto back; } tpctl->rf_atten = 5; if (rf->rf_type != BWI_RF_T_BCM2050) { if (rf->rf_type == BWI_RF_T_BCM2053 && rf->rf_rev == 1) tpctl->rf_atten = 6; goto back; } /* * NB: If we reaches here and the card is BRCM_BCM4309G, * then the card's PCI revision must >= 0x51 */ /* BCM2050 RF */ switch (rf->rf_rev) { case 1: if (phy->phy_mode == IEEE80211_MODE_11G) { if (BWI_IS_BRCM_BCM4309G(sc) || BWI_IS_BRCM_BU4306(sc)) tpctl->rf_atten = 3; else tpctl->rf_atten = 1; } else { if (BWI_IS_BRCM_BCM4309G(sc)) tpctl->rf_atten = 7; else tpctl->rf_atten = 6; } break; case 2: if (phy->phy_mode == IEEE80211_MODE_11G) { /* * NOTE: Order of following conditions is critical */ if (BWI_IS_BRCM_BCM4309G(sc)) tpctl->rf_atten = 3; else if (BWI_IS_BRCM_BU4306(sc)) tpctl->rf_atten = 5; else if (sc->sc_bbp_id == BWI_BBPID_BCM4320) tpctl->rf_atten = 4; else tpctl->rf_atten = 3; } else { tpctl->rf_atten = 6; } break; case 4: case 5: tpctl->rf_atten = 1; break; case 8: tpctl->rf_atten = 0x1a; break; } back: DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_INIT | BWI_DBG_TXPOWER, "bbp atten: %u, rf atten: %u, ctrl1: %u, ctrl2: %u\n", tpctl->bbp_atten, tpctl->rf_atten, tpctl->tp_ctrl1, tpctl->tp_ctrl2); } static void bwi_mac_dummy_xmit(struct bwi_mac *mac) { #define PACKET_LEN 5 static const uint32_t packet_11a[PACKET_LEN] = { 0x000201cc, 0x00d40000, 0x00000000, 0x01000000, 0x00000000 }; static const uint32_t packet_11bg[PACKET_LEN] = { 0x000b846e, 0x00d40000, 0x00000000, 0x01000000, 0x00000000 }; struct bwi_softc *sc = mac->mac_sc; struct bwi_rf *rf = &mac->mac_rf; const uint32_t *packet; uint16_t val_50c; int wait_max, i; if (mac->mac_phy.phy_mode == IEEE80211_MODE_11A) { wait_max = 30; packet = packet_11a; val_50c = 1; } else { wait_max = 250; packet = packet_11bg; val_50c = 0; } for (i = 0; i < PACKET_LEN; ++i) TMPLT_WRITE_4(mac, i * 4, packet[i]); CSR_READ_4(sc, BWI_MAC_STATUS); /* dummy read */ CSR_WRITE_2(sc, 0x568, 0); CSR_WRITE_2(sc, 0x7c0, 0); CSR_WRITE_2(sc, 0x50c, val_50c); CSR_WRITE_2(sc, 0x508, 0); CSR_WRITE_2(sc, 0x50a, 0); CSR_WRITE_2(sc, 0x54c, 0); CSR_WRITE_2(sc, 0x56a, 0x14); CSR_WRITE_2(sc, 0x568, 0x826); CSR_WRITE_2(sc, 0x500, 0); CSR_WRITE_2(sc, 0x502, 0x30); if (rf->rf_type == BWI_RF_T_BCM2050 && rf->rf_rev <= 5) RF_WRITE(mac, 0x51, 0x17); for (i = 0; i < wait_max; ++i) { if (CSR_READ_2(sc, 0x50e) & 0x80) break; DELAY(10); } for (i = 0; i < 10; ++i) { if (CSR_READ_2(sc, 0x50e) & 0x400) break; DELAY(10); } for (i = 0; i < 10; ++i) { if ((CSR_READ_2(sc, 0x690) & 0x100) == 0) break; DELAY(10); } if (rf->rf_type == BWI_RF_T_BCM2050 && rf->rf_rev <= 5) RF_WRITE(mac, 0x51, 0x37); #undef PACKET_LEN } static void bwi_mac_init_tpctl_11bg(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct bwi_phy *phy = &mac->mac_phy; struct bwi_rf *rf = &mac->mac_rf; struct bwi_tpctl tpctl_orig; int restore_tpctl = 0; KASSERT(phy->phy_mode != IEEE80211_MODE_11A); if (BWI_IS_BRCM_BU4306(sc)) return; PHY_WRITE(mac, 0x28, 0x8018); CSR_CLRBITS_2(sc, BWI_BBP_ATTEN, 0x20); if (phy->phy_mode == IEEE80211_MODE_11G) { if ((phy->phy_flags & BWI_PHY_F_LINKED) == 0) return; PHY_WRITE(mac, 0x47a, 0xc111); } if (mac->mac_flags & BWI_MAC_F_TPCTL_INITED) return; if (phy->phy_mode == IEEE80211_MODE_11B && phy->phy_rev >= 2 && rf->rf_type == BWI_RF_T_BCM2050) { RF_SETBITS(mac, 0x76, 0x84); } else { struct bwi_tpctl tpctl; /* Backup original TX power control variables */ memcpy(&tpctl_orig, &mac->mac_tpctl, sizeof(tpctl_orig)); restore_tpctl = 1; memcpy(&tpctl, &mac->mac_tpctl, sizeof(tpctl)); tpctl.bbp_atten = 11; tpctl.tp_ctrl1 = 0; #ifdef notyet if (rf->rf_rev >= 6 && rf->rf_rev <= 8) tpctl.rf_atten = 31; else #endif tpctl.rf_atten = 9; bwi_mac_set_tpctl_11bg(mac, &tpctl); } bwi_mac_dummy_xmit(mac); mac->mac_flags |= BWI_MAC_F_TPCTL_INITED; rf->rf_base_tssi = PHY_READ(mac, 0x29); DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_INIT | BWI_DBG_TXPOWER, "base tssi %d\n", rf->rf_base_tssi); if (abs(rf->rf_base_tssi - rf->rf_idle_tssi) >= 20) { aprint_error_dev(sc->sc_dev, "base tssi measure failed\n"); mac->mac_flags |= BWI_MAC_F_TPCTL_ERROR; } if (restore_tpctl) bwi_mac_set_tpctl_11bg(mac, &tpctl_orig); else RF_CLRBITS(mac, 0x76, 0x84); bwi_rf_clear_tssi(mac); } static void bwi_mac_detach(struct bwi_mac *mac) { bwi_mac_fw_free(mac); } static int bwi_mac_fw_alloc(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; int idx, error; error = bwi_mac_fw_image_alloc(mac, BWI_FW_UCODE_PREFIX, mac->mac_rev >= 5 ? 5 : mac->mac_rev, &mac->mac_ucode_fwi, BWI_FW_T_UCODE); if (error) goto fail_ucode; error = bwi_mac_fw_image_alloc(mac, BWI_FW_PCM_PREFIX, mac->mac_rev >= 5 ? 5 : mac->mac_rev, &mac->mac_pcm_fwi, BWI_FW_T_PCM); if (error) goto fail_pcm; /* TODO: 11A */ if (mac->mac_rev == 2 || mac->mac_rev == 4) idx = 2; else if (mac->mac_rev >= 5 && mac->mac_rev <= 20) idx = 5; else { aprint_error_dev(sc->sc_dev, "no suitable IV for MAC rev %d\n", mac->mac_rev); error = ENODEV; goto fail_iv; } error = bwi_mac_fw_image_alloc(mac, BWI_FW_IV_PREFIX, idx, &mac->mac_iv_fwi, BWI_FW_T_IV); if (error) goto fail_iv; /* TODO: 11A */ if (mac->mac_rev == 2 || mac->mac_rev == 4 || mac->mac_rev >= 11) /* No extended IV */ goto back; else if (mac->mac_rev >= 5 && mac->mac_rev <= 10) idx = 5; else { aprint_error_dev(sc->sc_dev, "no suitable ExtIV for MAC rev %d\n", mac->mac_rev); error = ENODEV; goto fail_iv_ext; } error = bwi_mac_fw_image_alloc(mac, BWI_FW_IV_EXT_PREFIX, idx, &mac->mac_iv_ext_fwi, BWI_FW_T_IV); if (error) goto fail_iv_ext; back: return (0); fail_iv_ext: bwi_mac_fw_image_free(mac, &mac->mac_iv_fwi); fail_iv: bwi_mac_fw_image_free(mac, &mac->mac_pcm_fwi); fail_pcm: bwi_mac_fw_image_free(mac, &mac->mac_ucode_fwi); fail_ucode: return (error); } static void bwi_mac_fw_free(struct bwi_mac *mac) { bwi_mac_fw_image_free(mac, &mac->mac_ucode_fwi); bwi_mac_fw_image_free(mac, &mac->mac_pcm_fwi); bwi_mac_fw_image_free(mac, &mac->mac_iv_fwi); bwi_mac_fw_image_free(mac, &mac->mac_iv_ext_fwi); } static int bwi_mac_fw_image_alloc(struct bwi_mac *mac, const char *prefix, int idx, struct bwi_fw_image *fwi, uint8_t fw_type) { struct bwi_softc *sc = mac->mac_sc; char *fw_name = fwi->fwi_name; size_t fw_name_size = sizeof(fwi->fwi_name); firmware_handle_t fwh; const struct bwi_fwhdr *hdr; int error; /* [TRC: XXX ???] */ if (fwi->fwi_data != NULL) return (0); snprintf(fw_name, fw_name_size, BWI_FW_NAME_FORMAT, sc->sc_fw_version, prefix, idx); DPRINTF(sc, BWI_DBG_FIRMWARE, "opening firmware %s\n", fw_name); error = firmware_open("bwi", fw_name, &fwh); if (error) { aprint_error_dev(sc->sc_dev, "firmware_open failed on %s\n", fw_name); goto fail; } fwi->fwi_size = firmware_get_size(fwh); if (fwi->fwi_size < sizeof(struct bwi_fwhdr)) { aprint_error_dev(sc->sc_dev, "firmware image %s has no header\n", fw_name); error = EIO; goto fail; } DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_INIT | BWI_DBG_FIRMWARE, "firmware image %s, size %zx\n", fw_name, fwi->fwi_size); fwi->fwi_data = firmware_malloc(fwi->fwi_size); if (fwi->fwi_data == NULL) { error = ENOMEM; firmware_close(fwh); goto fail; } DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_INIT | BWI_DBG_FIRMWARE, "firmware image %s loaded at %p\n", fw_name, fwi->fwi_data); fwi->fwi_data = firmware_malloc(fwi->fwi_size); error = firmware_read(fwh, 0, fwi->fwi_data, fwi->fwi_size); firmware_close(fwh); if (error) goto free_and_fail; hdr = (const struct bwi_fwhdr *)fwi->fwi_data; if (fw_type != BWI_FW_T_IV) { /* * Don't verify IV's size, it has different meaning */ size_t fw_size = (size_t)be32toh(hdr->fw_size); if (fw_size != fwi->fwi_size - sizeof(*hdr)) { aprint_error_dev(sc->sc_dev, "firmware image %s" " size mismatch, fw %zx, real %zx\n", fw_name, fw_size, fwi->fwi_size - sizeof(*hdr)); goto invalid; } } if (hdr->fw_type != fw_type) { aprint_error_dev(sc->sc_dev, "firmware image %s" " type mismatch, fw `%c', target `%c'\n", fw_name, hdr->fw_type, fw_type); goto invalid; } if (hdr->fw_gen != BWI_FW_GEN_1) { aprint_error_dev(sc->sc_dev, "firmware image %s" " generation mismatch, fw %d, target %d\n", fw_name, hdr->fw_gen, BWI_FW_GEN_1); goto invalid; } DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_INIT | BWI_DBG_FIRMWARE, "firmware image %s loaded successfully\n", fw_name); return (0); invalid: error = EINVAL; free_and_fail: firmware_free(fwi->fwi_data, fwi->fwi_size); fwi->fwi_data = NULL; fwi->fwi_size = 0; fail: return (error); } static void bwi_mac_fw_image_free(struct bwi_mac *mac, struct bwi_fw_image *fwi) { if (fwi->fwi_data != NULL) { DPRINTF(mac->mac_sc, BWI_DBG_FIRMWARE, "freeing firmware %s\n", fwi->fwi_name); firmware_free(fwi->fwi_data, fwi->fwi_size); fwi->fwi_data = NULL; fwi->fwi_size = 0; } } static int bwi_mac_fw_load(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; const uint32_t *fw; uint16_t fw_rev; size_t fw_len, i; /* * Load ucode image */ fw = (const uint32_t *)(mac->mac_ucode + BWI_FWHDR_SZ); fw_len = (mac->mac_ucode_size - BWI_FWHDR_SZ) / sizeof(uint32_t); DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_INIT | BWI_DBG_FIRMWARE, "loading ucode image at %p, length %zx\n", fw, fw_len); CSR_WRITE_4(sc, BWI_MOBJ_CTRL, BWI_MOBJ_CTRL_VAL(BWI_FW_UCODE_MOBJ | BWI_WR_MOBJ_AUTOINC, 0)); for (i = 0; i < fw_len; ++i) { CSR_WRITE_4(sc, BWI_MOBJ_DATA, be32toh(fw[i])); DELAY(10); } /* * Load PCM image */ fw = (const uint32_t *)(mac->mac_pcm + BWI_FWHDR_SZ); fw_len = (mac->mac_pcm_size - BWI_FWHDR_SZ) / sizeof(uint32_t); DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_INIT | BWI_DBG_FIRMWARE, "loading PCM image at %p, length %zx\n", fw, fw_len); CSR_WRITE_4(sc, BWI_MOBJ_CTRL, BWI_MOBJ_CTRL_VAL(BWI_FW_PCM_MOBJ, 0x01ea)); CSR_WRITE_4(sc, BWI_MOBJ_DATA, 0x4000); CSR_WRITE_4(sc, BWI_MOBJ_CTRL, BWI_MOBJ_CTRL_VAL(BWI_FW_PCM_MOBJ, 0x01eb)); for (i = 0; i < fw_len; ++i) { CSR_WRITE_4(sc, BWI_MOBJ_DATA, be32toh(fw[i])); DELAY(10); } CSR_WRITE_4(sc, BWI_MAC_INTR_STATUS, BWI_ALL_INTRS); CSR_WRITE_4(sc, BWI_MAC_STATUS, BWI_MAC_STATUS_UCODE_START | BWI_MAC_STATUS_IHREN | BWI_MAC_STATUS_INFRA); #define NRETRY 200 for (i = 0; i < NRETRY; ++i) { uint32_t intr_status; intr_status = CSR_READ_4(sc, BWI_MAC_INTR_STATUS); if (intr_status == BWI_INTR_READY) break; DELAY(10); } if (i == NRETRY) { aprint_error_dev(sc->sc_dev, "timeout loading ucode & pcm firmware\n"); return (ETIMEDOUT); } #undef NRETRY CSR_READ_4(sc, BWI_MAC_INTR_STATUS); /* dummy read */ fw_rev = MOBJ_READ_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_FWREV); if (fw_rev > BWI_FW_VERSION3_REVMAX) { aprint_error_dev(sc->sc_dev, "firmware version 4 is not supported yet\n"); return (ENODEV); } aprint_normal_dev(sc->sc_dev, "firmware rev 0x%04x," " patch level 0x%04x\n", fw_rev, MOBJ_READ_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_FWPATCHLV)); return (0); } static int bwi_mac_gpio_init(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct bwi_regwin *old, *gpio_rw; uint32_t filt, bits; int error; CSR_CLRBITS_4(sc, BWI_MAC_STATUS, BWI_MAC_STATUS_GPOSEL_MASK); /* TODO: LED */ CSR_SETBITS_2(sc, BWI_MAC_GPIO_MASK, 0xf); filt = 0x1f; bits = 0xf; if (sc->sc_bbp_id == BWI_BBPID_BCM4301) { filt |= 0x60; bits |= 0x60; } if (sc->sc_card_flags & BWI_CARD_F_PA_GPIO9) { CSR_SETBITS_2(sc, BWI_MAC_GPIO_MASK, 0x200); filt |= 0x200; bits |= 0x200; } gpio_rw = BWI_GPIO_REGWIN(sc); error = bwi_regwin_switch(sc, gpio_rw, &old); if (error) return (error); CSR_FILT_SETBITS_4(sc, BWI_GPIO_CTRL, filt, bits); return (bwi_regwin_switch(sc, old, NULL)); } static int bwi_mac_gpio_fini(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct bwi_regwin *old, *gpio_rw; int error; gpio_rw = BWI_GPIO_REGWIN(sc); error = bwi_regwin_switch(sc, gpio_rw, &old); if (error) return (error); CSR_WRITE_4(sc, BWI_GPIO_CTRL, 0); return (bwi_regwin_switch(sc, old, NULL)); } static int bwi_mac_fw_load_iv(struct bwi_mac *mac, const struct bwi_fw_image *fwi) { struct bwi_softc *sc = mac->mac_sc; const struct bwi_fwhdr *hdr; const struct bwi_fw_iv *iv; size_t iv_img_size; int n, i; DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_INIT | BWI_DBG_FIRMWARE, "loading %s at %p\n", fwi->fwi_name, fwi->fwi_data); /* Get the number of IVs in the IV image */ hdr = (const struct bwi_fwhdr *)fwi->fwi_data; n = be32toh(hdr->fw_iv_cnt); DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_INIT | BWI_DBG_FIRMWARE, "IV count %d\n", n); /* Calculate the IV image size, for later sanity check */ iv_img_size = fwi->fwi_size - sizeof(*hdr); /* Locate the first IV */ iv = (const struct bwi_fw_iv *)(fwi->fwi_data + sizeof(*hdr)); for (i = 0; i < n; ++i) { uint16_t iv_ofs, ofs; int sz = 0; if (iv_img_size < sizeof(iv->iv_ofs)) { aprint_error_dev(sc->sc_dev, "invalid IV image, ofs\n"); return (EINVAL); } iv_img_size -= sizeof(iv->iv_ofs); sz += sizeof(iv->iv_ofs); iv_ofs = be16toh(iv->iv_ofs); ofs = __SHIFTOUT(iv_ofs, BWI_FW_IV_OFS_MASK); if (ofs >= 0x1000) { aprint_error_dev(sc->sc_dev, "invalid ofs (0x%04x) " "for %dth iv\n", ofs, i); return (EINVAL); } if (iv_ofs & BWI_FW_IV_IS_32BIT) { uint32_t val32; if (iv_img_size < sizeof(iv->iv_val.val32)) { aprint_error_dev(sc->sc_dev, "invalid IV image, val32\n"); return (EINVAL); } iv_img_size -= sizeof(iv->iv_val.val32); sz += sizeof(iv->iv_val.val32); val32 = be32toh(iv->iv_val.val32); CSR_WRITE_4(sc, ofs, val32); } else { uint16_t val16; if (iv_img_size < sizeof(iv->iv_val.val16)) { aprint_error_dev(sc->sc_dev, "invalid IV image, val16\n"); return (EINVAL); } iv_img_size -= sizeof(iv->iv_val.val16); sz += sizeof(iv->iv_val.val16); val16 = be16toh(iv->iv_val.val16); CSR_WRITE_2(sc, ofs, val16); } iv = (const struct bwi_fw_iv *)((const uint8_t *)iv + sz); } if (iv_img_size != 0) { aprint_error_dev(sc->sc_dev, "invalid IV image, size left %zx\n", iv_img_size); return (EINVAL); } return (0); } static int bwi_mac_fw_init(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; int error; error = bwi_mac_fw_load_iv(mac, &mac->mac_iv_fwi); if (error) { aprint_error_dev(sc->sc_dev, "load IV failed\n"); return (error); } if (mac->mac_iv_ext != NULL) { error = bwi_mac_fw_load_iv(mac, &mac->mac_iv_ext_fwi); if (error) aprint_error_dev(sc->sc_dev, "load ExtIV failed\n"); } return (error); } static void bwi_mac_opmode_init(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct ieee80211com *ic = &sc->sc_ic; uint32_t mac_status; uint16_t pre_tbtt; CSR_CLRBITS_4(sc, BWI_MAC_STATUS, BWI_MAC_STATUS_INFRA); CSR_SETBITS_4(sc, BWI_MAC_STATUS, BWI_MAC_STATUS_INFRA); CSR_SETBITS_4(sc, BWI_MAC_STATUS, BWI_MAC_STATUS_PASS_BCN); /* Set probe resp timeout to infinite */ MOBJ_WRITE_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_PROBE_RESP_TO, 0); /* * TODO: factor out following part */ mac_status = CSR_READ_4(sc, BWI_MAC_STATUS); mac_status &= ~(BWI_MAC_STATUS_OPMODE_HOSTAP | BWI_MAC_STATUS_PASS_CTL | BWI_MAC_STATUS_PASS_BADPLCP | BWI_MAC_STATUS_PASS_BADFCS | BWI_MAC_STATUS_PROMISC); mac_status |= BWI_MAC_STATUS_INFRA; /* Always turn on PROMISC on old hardware */ if (mac->mac_rev < 5) mac_status |= BWI_MAC_STATUS_PROMISC; switch (ic->ic_opmode) { case IEEE80211_M_IBSS: mac_status &= ~BWI_MAC_STATUS_INFRA; break; case IEEE80211_M_HOSTAP: mac_status |= BWI_MAC_STATUS_OPMODE_HOSTAP; break; case IEEE80211_M_MONITOR: #if 0 /* Do you want data from your microwave oven? */ mac_status |= BWI_MAC_STATUS_PASS_CTL | BWI_MAC_STATUS_PASS_BADPLCP | BWI_MAC_STATUS_PASS_BADFCS; #else mac_status |= BWI_MAC_STATUS_PASS_CTL; #endif /* Promisc? */ break; default: break; } if (sc->sc_if.if_flags & IFF_PROMISC) mac_status |= BWI_MAC_STATUS_PROMISC; CSR_WRITE_4(sc, BWI_MAC_STATUS, mac_status); if (ic->ic_opmode != IEEE80211_M_IBSS && ic->ic_opmode != IEEE80211_M_HOSTAP) { if (sc->sc_bbp_id == BWI_BBPID_BCM4306 && sc->sc_bbp_rev == 3) pre_tbtt = 100; else pre_tbtt = 50; } else pre_tbtt = 2; CSR_WRITE_2(sc, BWI_MAC_PRE_TBTT, pre_tbtt); } static void bwi_mac_hostflags_init(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct bwi_phy *phy = &mac->mac_phy; struct bwi_rf *rf = &mac->mac_rf; uint64_t host_flags; if (phy->phy_mode == IEEE80211_MODE_11A) return; host_flags = HFLAGS_READ(mac); host_flags |= BWI_HFLAG_SYM_WA; if (phy->phy_mode == IEEE80211_MODE_11G) { if (phy->phy_rev == 1) host_flags |= BWI_HFLAG_GDC_WA; if (sc->sc_card_flags & BWI_CARD_F_PA_GPIO9) host_flags |= BWI_HFLAG_OFDM_PA; } else if (phy->phy_mode == IEEE80211_MODE_11B) { if (phy->phy_rev >= 2 && rf->rf_type == BWI_RF_T_BCM2050) host_flags &= ~BWI_HFLAG_GDC_WA; } else { panic("unknown PHY mode %u\n", phy->phy_mode); } HFLAGS_WRITE(mac, host_flags); } static void bwi_mac_bss_param_init(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct bwi_phy *phy = &mac->mac_phy; struct bwi_retry_lim lim; uint16_t cw_min; /* * Set short/long retry limits */ memset(&lim, 0, sizeof(lim)); lim.shretry = BWI_SHRETRY; lim.shretry_fb = BWI_SHRETRY_FB; lim.lgretry = BWI_LGRETRY; lim.lgretry_fb = BWI_LGRETRY_FB; bwi_mac_set_retry_lim(mac, &lim); /* * Implicitly prevent firmware from sending probe response * by setting its "probe response timeout" to 1us. */ MOBJ_WRITE_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_PROBE_RESP_TO, 1); /* * XXX MAC level acknowledge and CW min/max should depend * on the char rateset of the IBSS/BSS to join. */ /* * Set MAC level acknowledge rates */ bwi_mac_set_ackrates(mac, &sc->sc_ic.ic_sup_rates[phy->phy_mode]); /* * Set CW min */ if (phy->phy_mode == IEEE80211_MODE_11B) cw_min = IEEE80211_CW_MIN_0; else cw_min = IEEE80211_CW_MIN_1; MOBJ_WRITE_2(mac, BWI_80211_MOBJ, BWI_80211_MOBJ_CWMIN, cw_min); /* * Set CW max */ MOBJ_WRITE_2(mac, BWI_80211_MOBJ, BWI_80211_MOBJ_CWMAX, IEEE80211_CW_MAX); } static void bwi_mac_set_retry_lim(struct bwi_mac *mac, const struct bwi_retry_lim *lim) { /* Short/Long retry limit */ MOBJ_WRITE_2(mac, BWI_80211_MOBJ, BWI_80211_MOBJ_SHRETRY, lim->shretry); MOBJ_WRITE_2(mac, BWI_80211_MOBJ, BWI_80211_MOBJ_LGRETRY, lim->lgretry); /* Short/Long retry fallback limit */ MOBJ_WRITE_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_SHRETRY_FB, lim->shretry_fb); MOBJ_WRITE_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_LGRETEY_FB, lim->lgretry_fb); } static void bwi_mac_set_ackrates(struct bwi_mac *mac, const struct ieee80211_rateset *rs) { int i; /* XXX not standard conforming */ for (i = 0; i < rs->rs_nrates; ++i) { enum bwi_ieee80211_modtype modtype; uint16_t ofs; modtype = bwi_ieee80211_rate2modtype(rs->rs_rates[i]); switch (modtype) { case IEEE80211_MODTYPE_DS: ofs = 0x4c0; ofs += (bwi_ieee80211_rate2plcp(rs->rs_rates[i], IEEE80211_MODE_11B) & 0xf) * 2; break; case IEEE80211_MODTYPE_OFDM: ofs = 0x480; ofs += (bwi_ieee80211_rate2plcp(rs->rs_rates[i], IEEE80211_MODE_11G) & 0xf) * 2; break; default: panic("unsupported modtype %u\n", modtype); } MOBJ_WRITE_2(mac, BWI_COMM_MOBJ, ofs + 0x20, MOBJ_READ_2(mac, BWI_COMM_MOBJ, ofs)); } } static int bwi_mac_start(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; CSR_SETBITS_4(sc, BWI_MAC_STATUS, BWI_MAC_STATUS_ENABLE); CSR_WRITE_4(sc, BWI_MAC_INTR_STATUS, BWI_INTR_READY); /* Flush pending bus writes */ CSR_READ_4(sc, BWI_MAC_STATUS); CSR_READ_4(sc, BWI_MAC_INTR_STATUS); return (bwi_mac_config_ps(mac)); } static int bwi_mac_stop(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; int error, i; error = bwi_mac_config_ps(mac); if (error) return (error); CSR_CLRBITS_4(sc, BWI_MAC_STATUS, BWI_MAC_STATUS_ENABLE); /* Flush pending bus write */ CSR_READ_4(sc, BWI_MAC_STATUS); #define NRETRY 10000 for (i = 0; i < NRETRY; ++i) { if (CSR_READ_4(sc, BWI_MAC_INTR_STATUS) & BWI_INTR_READY) break; DELAY(1); } if (i == NRETRY) { aprint_error_dev(sc->sc_dev, "can't stop MAC\n"); return (ETIMEDOUT); } #undef NRETRY return (0); } static int bwi_mac_config_ps(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; uint32_t status; status = CSR_READ_4(sc, BWI_MAC_STATUS); status &= ~BWI_MAC_STATUS_HW_PS; status |= BWI_MAC_STATUS_WAKEUP; CSR_WRITE_4(sc, BWI_MAC_STATUS, status); /* Flush pending bus write */ CSR_READ_4(sc, BWI_MAC_STATUS); if (mac->mac_rev >= 5) { int i; #define NRETRY 100 for (i = 0; i < NRETRY; ++i) { if (MOBJ_READ_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_UCODE_STATE) != BWI_UCODE_STATE_PS) break; DELAY(10); } if (i == NRETRY) { aprint_error_dev(sc->sc_dev, "config PS failed\n"); return (ETIMEDOUT); } #undef NRETRY } return (0); } static void bwi_mac_reset_hwkeys(struct bwi_mac *mac) { /* TODO: firmware crypto */ MOBJ_READ_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_KEYTABLE_OFS); } static void bwi_mac_shutdown(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; int i; if (mac->mac_flags & BWI_MAC_F_HAS_TXSTATS) (sc->sc_free_txstats)(sc); (sc->sc_free_rx_ring)(sc); for (i = 0; i < BWI_TX_NRING; ++i) (sc->sc_free_tx_ring)(sc, i); bwi_rf_off(mac); /* TODO: LED */ bwi_mac_gpio_fini(mac); bwi_rf_off(mac); /* XXX again */ CSR_WRITE_2(sc, BWI_BBP_ATTEN, BWI_BBP_ATTEN_MAGIC); bwi_regwin_disable(sc, &mac->mac_regwin, 0); mac->mac_flags &= ~BWI_MAC_F_INITED; } static int bwi_mac_get_property(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; enum bwi_bus_space old_bus_space; uint32_t val; /* * Byte swap */ val = CSR_READ_4(sc, BWI_MAC_STATUS); if (val & BWI_MAC_STATUS_BSWAP) { DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_ATTACH, "need byte swap\n"); mac->mac_flags |= BWI_MAC_F_BSWAP; } /* * DMA address space */ old_bus_space = sc->sc_bus_space; val = CSR_READ_4(sc, BWI_STATE_HI); if (__SHIFTOUT(val, BWI_STATE_HI_FLAGS_MASK) & BWI_STATE_HI_FLAG_64BIT) { /* 64bit address */ sc->sc_bus_space = BWI_BUS_SPACE_64BIT; DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_ATTACH, "64bit bus space\n"); } else { uint32_t txrx_reg = BWI_TXRX_CTRL_BASE + BWI_TX32_CTRL; CSR_WRITE_4(sc, txrx_reg, BWI_TXRX32_CTRL_ADDRHI_MASK); if (CSR_READ_4(sc, txrx_reg) & BWI_TXRX32_CTRL_ADDRHI_MASK) { /* 32bit address */ sc->sc_bus_space = BWI_BUS_SPACE_32BIT; DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_ATTACH, "32bit bus space\n"); } else { /* 30bit address */ sc->sc_bus_space = BWI_BUS_SPACE_30BIT; DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_ATTACH, "30bit bus space\n"); } } if (old_bus_space != 0 && old_bus_space != sc->sc_bus_space) { aprint_error_dev(sc->sc_dev, "MACs bus space mismatch!\n"); return (ENXIO); } return (0); } static void bwi_mac_updateslot(struct bwi_mac *mac, int shslot) { uint16_t slot_time; if (mac->mac_phy.phy_mode == IEEE80211_MODE_11B) return; if (shslot) slot_time = IEEE80211_DUR_SHSLOT; else slot_time = IEEE80211_DUR_SLOT; CSR_WRITE_2(mac->mac_sc, BWI_MAC_SLOTTIME, slot_time + BWI_MAC_SLOTTIME_ADJUST); MOBJ_WRITE_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_SLOTTIME, slot_time); } static int bwi_mac_attach(struct bwi_softc *sc, int id, uint8_t rev) { struct bwi_mac *mac; int i; KASSERT(sc->sc_nmac <= BWI_MAC_MAX && sc->sc_nmac >= 0); if (sc->sc_nmac == BWI_MAC_MAX) { aprint_error_dev(sc->sc_dev, "too many MACs\n"); return (0); } /* * More than one MAC is only supported by BCM4309 */ if (sc->sc_nmac != 0 && sc->sc_pci_did != PCI_PRODUCT_BROADCOM_BCM4309) { DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_ATTACH, "ignore %dth MAC\n", sc->sc_nmac); return (0); } mac = &sc->sc_mac[sc->sc_nmac]; /* XXX will this happen? */ if (BWI_REGWIN_EXIST(&mac->mac_regwin)) { aprint_error_dev(sc->sc_dev, "%dth MAC already attached\n", sc->sc_nmac); return (0); } /* * Test whether the revision of this MAC is supported */ for (i = 0; i < __arraycount(bwi_sup_macrev); ++i) { if (bwi_sup_macrev[i] == rev) break; } if (i == __arraycount(bwi_sup_macrev)) { aprint_error_dev(sc->sc_dev, "MAC rev %u is not supported\n", rev); return (ENXIO); } BWI_CREATE_MAC(mac, sc, id, rev); sc->sc_nmac++; if (mac->mac_rev < 5) { mac->mac_flags |= BWI_MAC_F_HAS_TXSTATS; DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_ATTACH, "has TX stats\n"); } else { mac->mac_flags |= BWI_MAC_F_PHYE_RESET; } aprint_normal_dev(sc->sc_dev, "MAC: rev %u\n", rev); return (0); } static void bwi_mac_balance_atten(int *bbp_atten0, int *rf_atten0) { int bbp_atten, rf_atten, rf_atten_lim = -1; bbp_atten = *bbp_atten0; rf_atten = *rf_atten0; /* * RF attenuation affects TX power BWI_RF_ATTEN_FACTOR times * as much as BBP attenuation, so we try our best to keep RF * attenuation within range. BBP attenuation will be clamped * later if it is out of range during balancing. * * BWI_RF_ATTEN_MAX0 is used as RF attenuation upper limit. */ /* * Use BBP attenuation to balance RF attenuation */ if (rf_atten < 0) rf_atten_lim = 0; else if (rf_atten > BWI_RF_ATTEN_MAX0) rf_atten_lim = BWI_RF_ATTEN_MAX0; if (rf_atten_lim >= 0) { bbp_atten += (BWI_RF_ATTEN_FACTOR * (rf_atten - rf_atten_lim)); rf_atten = rf_atten_lim; } /* * If possible, use RF attenuation to balance BBP attenuation * NOTE: RF attenuation is still kept within range. */ while (rf_atten < BWI_RF_ATTEN_MAX0 && bbp_atten > BWI_BBP_ATTEN_MAX) { bbp_atten -= BWI_RF_ATTEN_FACTOR; ++rf_atten; } while (rf_atten > 0 && bbp_atten < 0) { bbp_atten += BWI_RF_ATTEN_FACTOR; --rf_atten; } /* RF attenuation MUST be within range */ KASSERT(rf_atten >= 0 && rf_atten <= BWI_RF_ATTEN_MAX0); /* * Clamp BBP attenuation */ if (bbp_atten < 0) bbp_atten = 0; else if (bbp_atten > BWI_BBP_ATTEN_MAX) bbp_atten = BWI_BBP_ATTEN_MAX; *rf_atten0 = rf_atten; *bbp_atten0 = bbp_atten; } static void bwi_mac_adjust_tpctl(struct bwi_mac *mac, int rf_atten_adj, int bbp_atten_adj) { struct bwi_softc *sc = mac->mac_sc; struct bwi_rf *rf = &mac->mac_rf; struct bwi_tpctl tpctl; int bbp_atten, rf_atten, tp_ctrl1; memcpy(&tpctl, &mac->mac_tpctl, sizeof(tpctl)); /* NOTE: Use signed value to do calulation */ bbp_atten = tpctl.bbp_atten; rf_atten = tpctl.rf_atten; tp_ctrl1 = tpctl.tp_ctrl1; bbp_atten += bbp_atten_adj; rf_atten += rf_atten_adj; bwi_mac_balance_atten(&bbp_atten, &rf_atten); if (rf->rf_type == BWI_RF_T_BCM2050 && rf->rf_rev == 2) { if (rf_atten <= 1) { if (tp_ctrl1 == 0) { tp_ctrl1 = 3; bbp_atten += 2; rf_atten += 2; } else if (sc->sc_card_flags & BWI_CARD_F_PA_GPIO9) { bbp_atten += (BWI_RF_ATTEN_FACTOR * (rf_atten - 2)); rf_atten = 2; } } else if (rf_atten > 4 && tp_ctrl1 != 0) { tp_ctrl1 = 0; if (bbp_atten < 3) { bbp_atten += 2; rf_atten -= 3; } else { bbp_atten -= 2; rf_atten -= 2; } } bwi_mac_balance_atten(&bbp_atten, &rf_atten); } tpctl.bbp_atten = bbp_atten; tpctl.rf_atten = rf_atten; tpctl.tp_ctrl1 = tp_ctrl1; bwi_mac_lock(mac); bwi_mac_set_tpctl_11bg(mac, &tpctl); bwi_mac_unlock(mac); } /* * http://bcm-specs.sipsolutions.net/RecalculateTransmissionPower */ static void bwi_mac_calibrate_txpower(struct bwi_mac *mac, enum bwi_txpwrcb_type type) { struct bwi_softc *sc = mac->mac_sc; struct bwi_rf *rf = &mac->mac_rf; int8_t tssi[4], tssi_avg, cur_txpwr; int error, i, ofdm_tssi; int txpwr_diff, rf_atten_adj, bbp_atten_adj; if (!sc->sc_txpwr_calib) return; if (mac->mac_flags & BWI_MAC_F_TPCTL_ERROR) { DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_TXPOWER, "tpctl error happened, can't set txpower\n"); return; } if (BWI_IS_BRCM_BU4306(sc)) { DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_TXPOWER, "BU4306, can't set txpower\n"); return; } /* * Save latest TSSI and reset the related memory objects */ ofdm_tssi = 0; error = bwi_rf_get_latest_tssi(mac, tssi, BWI_COMM_MOBJ_TSSI_DS); if (error) { DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_TXPOWER, "no DS tssi\n"); if (mac->mac_phy.phy_mode == IEEE80211_MODE_11B) { if (type == BWI_TXPWR_FORCE) { rf_atten_adj = 0; bbp_atten_adj = 1; goto calib; } else { return; } } error = bwi_rf_get_latest_tssi(mac, tssi, BWI_COMM_MOBJ_TSSI_OFDM); if (error) { DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_TXPOWER, "no OFDM tssi\n"); if (type == BWI_TXPWR_FORCE) { rf_atten_adj = 0; bbp_atten_adj = 1; goto calib; } else { return; } } for (i = 0; i < 4; ++i) { tssi[i] += 0x20; tssi[i] &= 0x3f; } ofdm_tssi = 1; } bwi_rf_clear_tssi(mac); DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_TXPOWER, "tssi0 %d, tssi1 %d, tssi2 %d, tssi3 %d\n", tssi[0], tssi[1], tssi[2], tssi[3]); /* * Calculate RF/BBP attenuation adjustment based on * the difference between desired TX power and sampled * TX power. */ /* +8 == "each incremented by 1/2" */ tssi_avg = (tssi[0] + tssi[1] + tssi[2] + tssi[3] + 8) / 4; if (ofdm_tssi && (HFLAGS_READ(mac) & BWI_HFLAG_PWR_BOOST_DS)) tssi_avg -= 13; DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_TXPOWER, "tssi avg %d\n", tssi_avg); error = bwi_rf_tssi2dbm(mac, tssi_avg, &cur_txpwr); if (error) return; DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_TXPOWER, "current txpower %d\n", cur_txpwr); txpwr_diff = rf->rf_txpower_max - cur_txpwr; /* XXX ni_txpower */ rf_atten_adj = -howmany(txpwr_diff, 8); if (type == BWI_TXPWR_INIT) { /* * Move toward EEPROM max TX power as fast as we can */ bbp_atten_adj = -txpwr_diff; } else { bbp_atten_adj = -(txpwr_diff / 2); } bbp_atten_adj -= (BWI_RF_ATTEN_FACTOR * rf_atten_adj); if (rf_atten_adj == 0 && bbp_atten_adj == 0) { DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_TXPOWER, "%s\n", "no need to adjust RF/BBP attenuation"); /* TODO: LO */ return; } calib: DPRINTF(sc, BWI_DBG_MAC | BWI_DBG_TXPOWER, "rf atten adjust %d, bbp atten adjust %d\n", rf_atten_adj, bbp_atten_adj); bwi_mac_adjust_tpctl(mac, rf_atten_adj, bbp_atten_adj); /* TODO: LO */ } static void bwi_mac_lock(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct ieee80211com *ic = &sc->sc_ic; KASSERT((mac->mac_flags & BWI_MAC_F_LOCKED) == 0); if (mac->mac_rev < 3) bwi_mac_stop(mac); else if (ic->ic_opmode != IEEE80211_M_HOSTAP) bwi_mac_config_ps(mac); CSR_SETBITS_4(sc, BWI_MAC_STATUS, BWI_MAC_STATUS_RFLOCK); /* Flush pending bus write */ CSR_READ_4(sc, BWI_MAC_STATUS); DELAY(10); mac->mac_flags |= BWI_MAC_F_LOCKED; } static void bwi_mac_unlock(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct ieee80211com *ic = &sc->sc_ic; KASSERT(mac->mac_flags & BWI_MAC_F_LOCKED); CSR_READ_2(sc, BWI_PHYINFO); /* dummy read */ CSR_CLRBITS_4(sc, BWI_MAC_STATUS, BWI_MAC_STATUS_RFLOCK); if (mac->mac_rev < 3) bwi_mac_start(mac); else if (ic->ic_opmode != IEEE80211_M_HOSTAP) bwi_mac_config_ps(mac); mac->mac_flags &= ~BWI_MAC_F_LOCKED; } static void bwi_mac_set_promisc(struct bwi_mac *mac, int promisc) { struct bwi_softc *sc = mac->mac_sc; if (mac->mac_rev < 5) /* Promisc is always on */ return; if (promisc) CSR_SETBITS_4(sc, BWI_MAC_STATUS, BWI_MAC_STATUS_PROMISC); else CSR_CLRBITS_4(sc, BWI_MAC_STATUS, BWI_MAC_STATUS_PROMISC); } /* PHY */ static void bwi_phy_write(struct bwi_mac *mac, uint16_t ctrl, uint16_t data) { struct bwi_softc *sc = mac->mac_sc; /* TODO: 11A */ CSR_WRITE_2(sc, BWI_PHY_CTRL, ctrl); CSR_WRITE_2(sc, BWI_PHY_DATA, data); } static uint16_t bwi_phy_read(struct bwi_mac *mac, uint16_t ctrl) { struct bwi_softc *sc = mac->mac_sc; /* TODO: 11A */ CSR_WRITE_2(sc, BWI_PHY_CTRL, ctrl); return (CSR_READ_2(sc, BWI_PHY_DATA)); } static int bwi_phy_attach(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct bwi_phy *phy = &mac->mac_phy; uint8_t phyrev, phytype, phyver; uint16_t val; int i; /* Get PHY type/revision/version */ val = CSR_READ_2(sc, BWI_PHYINFO); phyrev = __SHIFTOUT(val, BWI_PHYINFO_REV_MASK); phytype = __SHIFTOUT(val, BWI_PHYINFO_TYPE_MASK); phyver = __SHIFTOUT(val, BWI_PHYINFO_VER_MASK); aprint_normal_dev(sc->sc_dev, "PHY type %d, rev %d, ver %d\n", phytype, phyrev, phyver); /* * Verify whether the revision of the PHY type is supported * Convert PHY type to ieee80211_phymode */ switch (phytype) { case BWI_PHYINFO_TYPE_11A: if (phyrev >= 4) { aprint_error_dev(sc->sc_dev, "unsupported 11A PHY, rev %u\n", phyrev); return (ENXIO); } phy->phy_init = bwi_phy_init_11a; phy->phy_mode = IEEE80211_MODE_11A; phy->phy_tbl_ctrl = BWI_PHYR_TBL_CTRL_11A; phy->phy_tbl_data_lo = BWI_PHYR_TBL_DATA_LO_11A; phy->phy_tbl_data_hi = BWI_PHYR_TBL_DATA_HI_11A; break; case BWI_PHYINFO_TYPE_11B: for (i = 0; i < __arraycount(bwi_sup_bphy); ++i) { if (phyrev == bwi_sup_bphy[i].rev) { phy->phy_init = bwi_sup_bphy[i].init; break; } } if (i == __arraycount(bwi_sup_bphy)) { aprint_error_dev(sc->sc_dev, "unsupported 11B PHY, rev %u\n", phyrev); return (ENXIO); } phy->phy_mode = IEEE80211_MODE_11B; break; case BWI_PHYINFO_TYPE_11G: if (phyrev > 8) { aprint_error_dev(sc->sc_dev, "unsupported 11G PHY, rev %u\n", phyrev); return (ENXIO); } phy->phy_init = bwi_phy_init_11g; phy->phy_mode = IEEE80211_MODE_11G; phy->phy_tbl_ctrl = BWI_PHYR_TBL_CTRL_11G; phy->phy_tbl_data_lo = BWI_PHYR_TBL_DATA_LO_11G; phy->phy_tbl_data_hi = BWI_PHYR_TBL_DATA_HI_11G; break; default: aprint_error_dev(sc->sc_dev, "unsupported PHY type %d\n", phytype); return (ENXIO); } phy->phy_rev = phyrev; phy->phy_version = phyver; return (0); } static void bwi_phy_set_bbp_atten(struct bwi_mac *mac, uint16_t bbp_atten) { struct bwi_phy *phy = &mac->mac_phy; uint16_t mask = 0x000f; if (phy->phy_version == 0) { CSR_FILT_SETBITS_2(mac->mac_sc, BWI_BBP_ATTEN, ~mask, __SHIFTIN(bbp_atten, mask)); } else { if (phy->phy_version > 1) mask <<= 2; else mask <<= 3; PHY_FILT_SETBITS(mac, BWI_PHYR_BBP_ATTEN, ~mask, __SHIFTIN(bbp_atten, mask)); } } static int bwi_phy_calibrate(struct bwi_mac *mac) { struct bwi_phy *phy = &mac->mac_phy; /* Dummy read */ CSR_READ_4(mac->mac_sc, BWI_MAC_STATUS); /* Don't re-init */ if (phy->phy_flags & BWI_PHY_F_CALIBRATED) return (0); if (phy->phy_mode == IEEE80211_MODE_11G && phy->phy_rev == 1) { bwi_mac_reset(mac, 0); bwi_phy_init_11g(mac); bwi_mac_reset(mac, 1); } phy->phy_flags |= BWI_PHY_F_CALIBRATED; return (0); } static void bwi_tbl_write_2(struct bwi_mac *mac, uint16_t ofs, uint16_t data) { struct bwi_phy *phy = &mac->mac_phy; KASSERT(phy->phy_tbl_ctrl != 0 && phy->phy_tbl_data_lo != 0); PHY_WRITE(mac, phy->phy_tbl_ctrl, ofs); PHY_WRITE(mac, phy->phy_tbl_data_lo, data); } static void bwi_tbl_write_4(struct bwi_mac *mac, uint16_t ofs, uint32_t data) { struct bwi_phy *phy = &mac->mac_phy; KASSERT(phy->phy_tbl_data_lo != 0 && phy->phy_tbl_data_hi != 0 && phy->phy_tbl_ctrl != 0); PHY_WRITE(mac, phy->phy_tbl_ctrl, ofs); PHY_WRITE(mac, phy->phy_tbl_data_hi, data >> 16); PHY_WRITE(mac, phy->phy_tbl_data_lo, data & 0xffff); } static void bwi_nrssi_write(struct bwi_mac *mac, uint16_t ofs, int16_t data) { PHY_WRITE(mac, BWI_PHYR_NRSSI_CTRL, ofs); PHY_WRITE(mac, BWI_PHYR_NRSSI_DATA, (uint16_t)data); } static int16_t bwi_nrssi_read(struct bwi_mac *mac, uint16_t ofs) { PHY_WRITE(mac, BWI_PHYR_NRSSI_CTRL, ofs); return ((int16_t)PHY_READ(mac, BWI_PHYR_NRSSI_DATA)); } static void bwi_phy_init_11a(struct bwi_mac *mac) { /* TODO: 11A */ } static void bwi_phy_init_11g(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct bwi_phy *phy = &mac->mac_phy; struct bwi_rf *rf = &mac->mac_rf; const struct bwi_tpctl *tpctl = &mac->mac_tpctl; if (phy->phy_rev == 1) bwi_phy_init_11b_rev5(mac); else bwi_phy_init_11b_rev6(mac); if (phy->phy_rev >= 2 || (phy->phy_flags & BWI_PHY_F_LINKED)) bwi_phy_config_11g(mac); if (phy->phy_rev >= 2) { PHY_WRITE(mac, 0x814, 0); PHY_WRITE(mac, 0x815, 0); if (phy->phy_rev == 2) { PHY_WRITE(mac, 0x811, 0); PHY_WRITE(mac, 0x15, 0xc0); } else if (phy->phy_rev > 5) { PHY_WRITE(mac, 0x811, 0x400); PHY_WRITE(mac, 0x15, 0xc0); } } if (phy->phy_rev >= 2 || (phy->phy_flags & BWI_PHY_F_LINKED)) { uint16_t val; val = PHY_READ(mac, 0x400) & 0xff; if (val == 3 || val == 5) { PHY_WRITE(mac, 0x4c2, 0x1816); PHY_WRITE(mac, 0x4c3, 0x8006); if (val == 5) { PHY_FILT_SETBITS(mac, 0x4cc, 0xff, 0x1f00); } } } if ((phy->phy_rev <= 2 && (phy->phy_flags & BWI_PHY_F_LINKED)) || phy->phy_rev >= 2) PHY_WRITE(mac, 0x47e, 0x78); if (rf->rf_rev == 8) { PHY_SETBITS(mac, 0x801, 0x80); PHY_SETBITS(mac, 0x43e, 0x4); } if (phy->phy_rev >= 2 && (phy->phy_flags & BWI_PHY_F_LINKED)) bwi_rf_get_gains(mac); if (rf->rf_rev != 8) bwi_rf_init(mac); if (tpctl->tp_ctrl2 == 0xffff) { bwi_rf_lo_update(mac); } else { if (rf->rf_type == BWI_RF_T_BCM2050 && rf->rf_rev == 8) { RF_WRITE(mac, 0x52, (tpctl->tp_ctrl1 << 4) | tpctl->tp_ctrl2); } else { RF_FILT_SETBITS(mac, 0x52, 0xfff0, tpctl->tp_ctrl2); } if (phy->phy_rev >= 6) { PHY_FILT_SETBITS(mac, 0x36, 0xfff, tpctl->tp_ctrl2 << 12); } if (sc->sc_card_flags & BWI_CARD_F_PA_GPIO9) PHY_WRITE(mac, 0x2e, 0x8075); else PHY_WRITE(mac, 0x2e, 0x807f); if (phy->phy_rev < 2) PHY_WRITE(mac, 0x2f, 0x101); else PHY_WRITE(mac, 0x2f, 0x202); } if ((phy->phy_flags & BWI_PHY_F_LINKED) || phy->phy_rev >= 2) { bwi_rf_lo_adjust(mac, tpctl); PHY_WRITE(mac, 0x80f, 0x8078); } if ((sc->sc_card_flags & BWI_CARD_F_SW_NRSSI) == 0) { bwi_rf_init_hw_nrssi_table(mac, 0xffff /* XXX */); bwi_rf_set_nrssi_thr(mac); } else if ((phy->phy_flags & BWI_PHY_F_LINKED) || phy->phy_rev >= 2) { if (rf->rf_nrssi[0] == BWI_INVALID_NRSSI) { KASSERT(rf->rf_nrssi[1] == BWI_INVALID_NRSSI); bwi_rf_calc_nrssi_slope(mac); } else { KASSERT(rf->rf_nrssi[1] != BWI_INVALID_NRSSI); bwi_rf_set_nrssi_thr(mac); } } if (rf->rf_rev == 8) PHY_WRITE(mac, 0x805, 0x3230); bwi_mac_init_tpctl_11bg(mac); if (sc->sc_bbp_id == BWI_BBPID_BCM4306 && sc->sc_bbp_pkg == 2) { PHY_CLRBITS(mac, 0x429, 0x4000); PHY_CLRBITS(mac, 0x4c3, 0x8000); } } static void bwi_phy_init_11b_rev2(struct bwi_mac *mac) { struct bwi_softc *sc; sc = mac->mac_sc; /* TODO: 11B */ aprint_error_dev(sc->sc_dev, "%s is not implemented yet\n", __func__); } static void bwi_phy_init_11b_rev4(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct bwi_rf *rf = &mac->mac_rf; uint16_t val, ofs; uint chan; CSR_WRITE_2(sc, BWI_BPHY_CTRL, BWI_BPHY_CTRL_INIT); PHY_WRITE(mac, 0x20, 0x301c); PHY_WRITE(mac, 0x26, 0); PHY_WRITE(mac, 0x30, 0xc6); PHY_WRITE(mac, 0x88, 0x3e00); for (ofs = 0, val = 0x3c3d; ofs < 30; ++ofs, val -= 0x202) PHY_WRITE(mac, 0x89 + ofs, val); CSR_WRITE_2(sc, BWI_PHY_MAGIC_REG1, BWI_PHY_MAGIC_REG1_VAL1); chan = rf->rf_curchan; if (chan == IEEE80211_CHAN_ANY) chan = 6; /* Force to channel 6 */ bwi_rf_set_chan(mac, chan, 0); if (rf->rf_type != BWI_RF_T_BCM2050) { RF_WRITE(mac, 0x75, 0x80); RF_WRITE(mac, 0x79, 0x81); } RF_WRITE(mac, 0x50, 0x20); RF_WRITE(mac, 0x50, 0x23); if (rf->rf_type == BWI_RF_T_BCM2050) { RF_WRITE(mac, 0x50, 0x20); RF_WRITE(mac, 0x5a, 0x70); RF_WRITE(mac, 0x5b, 0x7b); RF_WRITE(mac, 0x5c, 0xb0); RF_WRITE(mac, 0x7a, 0xf); PHY_WRITE(mac, 0x38, 0x677); bwi_rf_init_bcm2050(mac); } PHY_WRITE(mac, 0x14, 0x80); PHY_WRITE(mac, 0x32, 0xca); if (rf->rf_type == BWI_RF_T_BCM2050) PHY_WRITE(mac, 0x32, 0xe0); PHY_WRITE(mac, 0x35, 0x7c2); bwi_rf_lo_update(mac); PHY_WRITE(mac, 0x26, 0xcc00); if (rf->rf_type == BWI_RF_T_BCM2050) PHY_WRITE(mac, 0x26, 0xce00); CSR_WRITE_2(sc, BWI_RF_CHAN_EX, 0x1100); PHY_WRITE(mac, 0x2a, 0x88a3); if (rf->rf_type == BWI_RF_T_BCM2050) PHY_WRITE(mac, 0x2a, 0x88c2); bwi_mac_set_tpctl_11bg(mac, NULL); if (sc->sc_card_flags & BWI_CARD_F_SW_NRSSI) { bwi_rf_calc_nrssi_slope(mac); bwi_rf_set_nrssi_thr(mac); } bwi_mac_init_tpctl_11bg(mac); } static void bwi_phy_init_11b_rev5(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct bwi_rf *rf = &mac->mac_rf; struct bwi_phy *phy = &mac->mac_phy; uint orig_chan; if (phy->phy_version == 1) RF_SETBITS(mac, 0x7a, 0x50); if (sc->sc_pci_subvid != PCI_VENDOR_BROADCOM && sc->sc_pci_subdid != BWI_PCI_SUBDEVICE_BU4306) { uint16_t ofs, val; val = 0x2120; for (ofs = 0xa8; ofs < 0xc7; ++ofs) { PHY_WRITE(mac, ofs, val); val += 0x202; } } PHY_FILT_SETBITS(mac, 0x35, 0xf0ff, 0x700); if (rf->rf_type == BWI_RF_T_BCM2050) PHY_WRITE(mac, 0x38, 0x667); if ((phy->phy_flags & BWI_PHY_F_LINKED) || phy->phy_rev >= 2) { if (rf->rf_type == BWI_RF_T_BCM2050) { RF_SETBITS(mac, 0x7a, 0x20); RF_SETBITS(mac, 0x51, 0x4); } CSR_WRITE_2(sc, BWI_RF_ANTDIV, 0); PHY_SETBITS(mac, 0x802, 0x100); PHY_SETBITS(mac, 0x42b, 0x2000); PHY_WRITE(mac, 0x1c, 0x186a); PHY_FILT_SETBITS(mac, 0x13, 0xff, 0x1900); PHY_FILT_SETBITS(mac, 0x35, 0xffc0, 0x64); PHY_FILT_SETBITS(mac, 0x5d, 0xff80, 0xa); } /* TODO: bad_frame_preempt? */ if (phy->phy_version == 1) { PHY_WRITE(mac, 0x26, 0xce00); PHY_WRITE(mac, 0x21, 0x3763); PHY_WRITE(mac, 0x22, 0x1bc3); PHY_WRITE(mac, 0x23, 0x6f9); PHY_WRITE(mac, 0x24, 0x37e); } else PHY_WRITE(mac, 0x26, 0xcc00); PHY_WRITE(mac, 0x30, 0xc6); CSR_WRITE_2(sc, BWI_BPHY_CTRL, BWI_BPHY_CTRL_INIT); if (phy->phy_version == 1) PHY_WRITE(mac, 0x20, 0x3e1c); else PHY_WRITE(mac, 0x20, 0x301c); if (phy->phy_version == 0) CSR_WRITE_2(sc, BWI_PHY_MAGIC_REG1, BWI_PHY_MAGIC_REG1_VAL1); /* Force to channel 7 */ orig_chan = rf->rf_curchan; bwi_rf_set_chan(mac, 7, 0); if (rf->rf_type != BWI_RF_T_BCM2050) { RF_WRITE(mac, 0x75, 0x80); RF_WRITE(mac, 0x79, 0x81); } RF_WRITE(mac, 0x50, 0x20); RF_WRITE(mac, 0x50, 0x23); if (rf->rf_type == BWI_RF_T_BCM2050) { RF_WRITE(mac, 0x50, 0x20); RF_WRITE(mac, 0x5a, 0x70); } RF_WRITE(mac, 0x5b, 0x7b); RF_WRITE(mac, 0x5c, 0xb0); RF_SETBITS(mac, 0x7a, 0x7); bwi_rf_set_chan(mac, orig_chan, 0); PHY_WRITE(mac, 0x14, 0x80); PHY_WRITE(mac, 0x32, 0xca); PHY_WRITE(mac, 0x2a, 0x88a3); bwi_mac_set_tpctl_11bg(mac, NULL); if (rf->rf_type == BWI_RF_T_BCM2050) RF_WRITE(mac, 0x5d, 0xd); CSR_FILT_SETBITS_2(sc, BWI_PHY_MAGIC_REG1, 0xffc0, 0x4); } static void bwi_phy_init_11b_rev6(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct bwi_rf *rf = &mac->mac_rf; struct bwi_phy *phy = &mac->mac_phy; uint16_t val, ofs; uint orig_chan; PHY_WRITE(mac, 0x3e, 0x817a); RF_SETBITS(mac, 0x7a, 0x58); if (rf->rf_rev == 4 || rf->rf_rev == 5) { RF_WRITE(mac, 0x51, 0x37); RF_WRITE(mac, 0x52, 0x70); RF_WRITE(mac, 0x53, 0xb3); RF_WRITE(mac, 0x54, 0x9b); RF_WRITE(mac, 0x5a, 0x88); RF_WRITE(mac, 0x5b, 0x88); RF_WRITE(mac, 0x5d, 0x88); RF_WRITE(mac, 0x5e, 0x88); RF_WRITE(mac, 0x7d, 0x88); HFLAGS_SETBITS(mac, BWI_HFLAG_MAGIC1); } else if (rf->rf_rev == 8) { RF_WRITE(mac, 0x51, 0); RF_WRITE(mac, 0x52, 0x40); RF_WRITE(mac, 0x53, 0xb7); RF_WRITE(mac, 0x54, 0x98); RF_WRITE(mac, 0x5a, 0x88); RF_WRITE(mac, 0x5b, 0x6b); RF_WRITE(mac, 0x5c, 0xf); if (sc->sc_card_flags & BWI_CARD_F_ALT_IQ) { RF_WRITE(mac, 0x5d, 0xfa); RF_WRITE(mac, 0x5e, 0xd8); } else { RF_WRITE(mac, 0x5d, 0xf5); RF_WRITE(mac, 0x5e, 0xb8); } RF_WRITE(mac, 0x73, 0x3); RF_WRITE(mac, 0x7d, 0xa8); RF_WRITE(mac, 0x7c, 0x1); RF_WRITE(mac, 0x7e, 0x8); } val = 0x1e1f; for (ofs = 0x88; ofs < 0x98; ++ofs) { PHY_WRITE(mac, ofs, val); val -= 0x202; } val = 0x3e3f; for (ofs = 0x98; ofs < 0xa8; ++ofs) { PHY_WRITE(mac, ofs, val); val -= 0x202; } val = 0x2120; for (ofs = 0xa8; ofs < 0xc8; ++ofs) { PHY_WRITE(mac, ofs, (val & 0x3f3f)); val += 0x202; } if (phy->phy_mode == IEEE80211_MODE_11G) { RF_SETBITS(mac, 0x7a, 0x20); RF_SETBITS(mac, 0x51, 0x4); PHY_SETBITS(mac, 0x802, 0x100); PHY_SETBITS(mac, 0x42b, 0x2000); PHY_WRITE(mac, 0x5b, 0); PHY_WRITE(mac, 0x5c, 0); } /* Force to channel 7 */ orig_chan = rf->rf_curchan; if (orig_chan >= 8) bwi_rf_set_chan(mac, 1, 0); else bwi_rf_set_chan(mac, 13, 0); RF_WRITE(mac, 0x50, 0x20); RF_WRITE(mac, 0x50, 0x23); DELAY(40); if (rf->rf_rev < 6 || rf->rf_rev == 8) { RF_SETBITS(mac, 0x7c, 0x2); RF_WRITE(mac, 0x50, 0x20); } if (rf->rf_rev <= 2) { RF_WRITE(mac, 0x7c, 0x20); RF_WRITE(mac, 0x5a, 0x70); RF_WRITE(mac, 0x5b, 0x7b); RF_WRITE(mac, 0x5c, 0xb0); } RF_FILT_SETBITS(mac, 0x7a, 0xf8, 0x7); bwi_rf_set_chan(mac, orig_chan, 0); PHY_WRITE(mac, 0x14, 0x200); if (rf->rf_rev >= 6) PHY_WRITE(mac, 0x2a, 0x88c2); else PHY_WRITE(mac, 0x2a, 0x8ac0); PHY_WRITE(mac, 0x38, 0x668); bwi_mac_set_tpctl_11bg(mac, NULL); if (rf->rf_rev <= 5) { PHY_FILT_SETBITS(mac, 0x5d, 0xff80, 0x3); if (rf->rf_rev <= 2) RF_WRITE(mac, 0x5d, 0xd); } if (phy->phy_version == 4) { CSR_WRITE_2(sc, BWI_PHY_MAGIC_REG1, BWI_PHY_MAGIC_REG1_VAL2); PHY_CLRBITS(mac, 0x61, 0xf000); } else { PHY_FILT_SETBITS(mac, 0x2, 0xffc0, 0x4); } if (phy->phy_mode == IEEE80211_MODE_11B) { CSR_WRITE_2(sc, BWI_BBP_ATTEN, BWI_BBP_ATTEN_MAGIC2); PHY_WRITE(mac, 0x16, 0x410); PHY_WRITE(mac, 0x17, 0x820); PHY_WRITE(mac, 0x62, 0x7); bwi_rf_init_bcm2050(mac); bwi_rf_lo_update(mac); if (sc->sc_card_flags & BWI_CARD_F_SW_NRSSI) { bwi_rf_calc_nrssi_slope(mac); bwi_rf_set_nrssi_thr(mac); } bwi_mac_init_tpctl_11bg(mac); } else CSR_WRITE_2(sc, BWI_BBP_ATTEN, 0); } static void bwi_phy_config_11g(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct bwi_phy *phy = &mac->mac_phy; const uint16_t *tbl; uint16_t wrd_ofs1, wrd_ofs2; int i, n; if (phy->phy_rev == 1) { PHY_WRITE(mac, 0x406, 0x4f19); PHY_FILT_SETBITS(mac, 0x429, 0xfc3f, 0x340); PHY_WRITE(mac, 0x42c, 0x5a); PHY_WRITE(mac, 0x427, 0x1a); /* Fill frequency table */ for (i = 0; i < __arraycount(bwi_phy_freq_11g_rev1); ++i) { bwi_tbl_write_2(mac, BWI_PHYTBL_FREQ + i, bwi_phy_freq_11g_rev1[i]); } /* Fill noise table */ for (i = 0; i < __arraycount(bwi_phy_noise_11g_rev1); ++i) { bwi_tbl_write_2(mac, BWI_PHYTBL_NOISE + i, bwi_phy_noise_11g_rev1[i]); } /* Fill rotor table */ for (i = 0; i < __arraycount(bwi_phy_rotor_11g_rev1); ++i) { /* NB: data length is 4 bytes */ bwi_tbl_write_4(mac, BWI_PHYTBL_ROTOR + i, bwi_phy_rotor_11g_rev1[i]); } } else { bwi_nrssi_write(mac, 0xba98, (int16_t)0x7654); /* XXX */ if (phy->phy_rev == 2) { PHY_WRITE(mac, 0x4c0, 0x1861); PHY_WRITE(mac, 0x4c1, 0x271); } else if (phy->phy_rev > 2) { PHY_WRITE(mac, 0x4c0, 0x98); PHY_WRITE(mac, 0x4c1, 0x70); PHY_WRITE(mac, 0x4c9, 0x80); } PHY_SETBITS(mac, 0x42b, 0x800); /* Fill RSSI table */ for (i = 0; i < 64; ++i) bwi_tbl_write_2(mac, BWI_PHYTBL_RSSI + i, i); /* Fill noise table */ for (i = 0; i < __arraycount(bwi_phy_noise_11g); ++i) { bwi_tbl_write_2(mac, BWI_PHYTBL_NOISE + i, bwi_phy_noise_11g[i]); } } /* * Fill noise scale table */ if (phy->phy_rev <= 2) { tbl = bwi_phy_noise_scale_11g_rev2; n = __arraycount(bwi_phy_noise_scale_11g_rev2); } else if (phy->phy_rev >= 7 && (PHY_READ(mac, 0x449) & 0x200)) { tbl = bwi_phy_noise_scale_11g_rev7; n = __arraycount(bwi_phy_noise_scale_11g_rev7); } else { tbl = bwi_phy_noise_scale_11g; n = __arraycount(bwi_phy_noise_scale_11g); } for (i = 0; i < n; ++i) bwi_tbl_write_2(mac, BWI_PHYTBL_NOISE_SCALE + i, tbl[i]); /* * Fill sigma square table */ if (phy->phy_rev == 2) { tbl = bwi_phy_sigma_sq_11g_rev2; n = __arraycount(bwi_phy_sigma_sq_11g_rev2); } else if (phy->phy_rev > 2 && phy->phy_rev <= 8) { tbl = bwi_phy_sigma_sq_11g_rev7; n = __arraycount(bwi_phy_sigma_sq_11g_rev7); } else { tbl = NULL; n = 0; } for (i = 0; i < n; ++i) bwi_tbl_write_2(mac, BWI_PHYTBL_SIGMA_SQ + i, tbl[i]); if (phy->phy_rev == 1) { /* Fill delay table */ for (i = 0; i < __arraycount(bwi_phy_delay_11g_rev1); ++i) { bwi_tbl_write_4(mac, BWI_PHYTBL_DELAY + i, bwi_phy_delay_11g_rev1[i]); } /* Fill WRSSI (Wide-Band RSSI) table */ for (i = 4; i < 20; ++i) bwi_tbl_write_2(mac, BWI_PHYTBL_WRSSI_REV1 + i, 0x20); bwi_phy_config_agc(mac); wrd_ofs1 = 0x5001; wrd_ofs2 = 0x5002; } else { /* Fill WRSSI (Wide-Band RSSI) table */ for (i = 0; i < 0x20; ++i) bwi_tbl_write_2(mac, BWI_PHYTBL_WRSSI + i, 0x820); bwi_phy_config_agc(mac); PHY_READ(mac, 0x400); /* Dummy read */ PHY_WRITE(mac, 0x403, 0x1000); bwi_tbl_write_2(mac, 0x3c02, 0xf); bwi_tbl_write_2(mac, 0x3c03, 0x14); wrd_ofs1 = 0x401; wrd_ofs2 = 0x402; } if (!(BWI_IS_BRCM_BU4306(sc) && sc->sc_pci_revid == 0x17)) { bwi_tbl_write_2(mac, wrd_ofs1, 0x2); bwi_tbl_write_2(mac, wrd_ofs2, 0x1); } /* phy->phy_flags & BWI_PHY_F_LINKED ? */ if (sc->sc_card_flags & BWI_CARD_F_PA_GPIO9) PHY_WRITE(mac, 0x46e, 0x3cf); } /* * Configure Automatic Gain Controller */ static void bwi_phy_config_agc(struct bwi_mac *mac) { struct bwi_phy *phy = &mac->mac_phy; uint16_t ofs; ofs = phy->phy_rev == 1 ? 0x4c00 : 0; bwi_tbl_write_2(mac, ofs, 0xfe); bwi_tbl_write_2(mac, ofs + 1, 0xd); bwi_tbl_write_2(mac, ofs + 2, 0x13); bwi_tbl_write_2(mac, ofs + 3, 0x19); if (phy->phy_rev == 1) { bwi_tbl_write_2(mac, 0x1800, 0x2710); bwi_tbl_write_2(mac, 0x1801, 0x9b83); bwi_tbl_write_2(mac, 0x1802, 0x9b83); bwi_tbl_write_2(mac, 0x1803, 0xf8d); PHY_WRITE(mac, 0x455, 0x4); } PHY_FILT_SETBITS(mac, 0x4a5, 0xff, 0x5700); PHY_FILT_SETBITS(mac, 0x41a, 0xff80, 0xf); PHY_FILT_SETBITS(mac, 0x41a, 0xc07f, 0x2b80); PHY_FILT_SETBITS(mac, 0x48c, 0xf0ff, 0x300); RF_SETBITS(mac, 0x7a, 0x8); PHY_FILT_SETBITS(mac, 0x4a0, 0xfff0, 0x8); PHY_FILT_SETBITS(mac, 0x4a1, 0xf0ff, 0x600); PHY_FILT_SETBITS(mac, 0x4a2, 0xf0ff, 0x700); PHY_FILT_SETBITS(mac, 0x4a0, 0xf0ff, 0x100); if (phy->phy_rev == 1) PHY_FILT_SETBITS(mac, 0x4a2, 0xfff0, 0x7); PHY_FILT_SETBITS(mac, 0x488, 0xff00, 0x1c); PHY_FILT_SETBITS(mac, 0x488, 0xc0ff, 0x200); PHY_FILT_SETBITS(mac, 0x496, 0xff00, 0x1c); PHY_FILT_SETBITS(mac, 0x489, 0xff00, 0x20); PHY_FILT_SETBITS(mac, 0x489, 0xc0ff, 0x200); PHY_FILT_SETBITS(mac, 0x482, 0xff00, 0x2e); PHY_FILT_SETBITS(mac, 0x496, 0xff, 0x1a00); PHY_FILT_SETBITS(mac, 0x481, 0xff00, 0x28); PHY_FILT_SETBITS(mac, 0x481, 0xff, 0x2c00); if (phy->phy_rev == 1) { PHY_WRITE(mac, 0x430, 0x92b); PHY_FILT_SETBITS(mac, 0x41b, 0xffe1, 0x2); } else { PHY_CLRBITS(mac, 0x41b, 0x1e); PHY_WRITE(mac, 0x41f, 0x287a); PHY_FILT_SETBITS(mac, 0x420, 0xfff0, 0x4); if (phy->phy_rev >= 6) { PHY_WRITE(mac, 0x422, 0x287a); PHY_FILT_SETBITS(mac, 0x420, 0xfff, 0x3000); } } PHY_FILT_SETBITS(mac, 0x4a8, 0x8080, 0x7874); PHY_WRITE(mac, 0x48e, 0x1c00); if (phy->phy_rev == 1) { PHY_FILT_SETBITS(mac, 0x4ab, 0xf0ff, 0x600); PHY_WRITE(mac, 0x48b, 0x5e); PHY_FILT_SETBITS(mac, 0x48c, 0xff00, 0x1e); PHY_WRITE(mac, 0x48d, 0x2); } bwi_tbl_write_2(mac, ofs + 0x800, 0); bwi_tbl_write_2(mac, ofs + 0x801, 7); bwi_tbl_write_2(mac, ofs + 0x802, 16); bwi_tbl_write_2(mac, ofs + 0x803, 28); if (phy->phy_rev >= 6) { PHY_CLRBITS(mac, 0x426, 0x3); PHY_CLRBITS(mac, 0x426, 0x1000); } } static void bwi_set_gains(struct bwi_mac *mac, const struct bwi_gains *gains) { struct bwi_phy *phy = &mac->mac_phy; uint16_t tbl_gain_ofs1, tbl_gain_ofs2, tbl_gain; int i; if (phy->phy_rev <= 1) { tbl_gain_ofs1 = 0x5000; tbl_gain_ofs2 = tbl_gain_ofs1 + 16; } else { tbl_gain_ofs1 = 0x400; tbl_gain_ofs2 = tbl_gain_ofs1 + 8; } for (i = 0; i < 4; ++i) { if (gains != NULL) { tbl_gain = gains->tbl_gain1; } else { /* Bit swap */ tbl_gain = (i & 0x1) << 1; tbl_gain |= (i & 0x2) >> 1; } bwi_tbl_write_2(mac, tbl_gain_ofs1 + i, tbl_gain); } for (i = 0; i < 16; ++i) { if (gains != NULL) tbl_gain = gains->tbl_gain2; else tbl_gain = i; bwi_tbl_write_2(mac, tbl_gain_ofs2 + i, tbl_gain); } if (gains == NULL || gains->phy_gain != -1) { uint16_t phy_gain1, phy_gain2; if (gains != NULL) { phy_gain1 = ((uint16_t)gains->phy_gain << 14) | ((uint16_t)gains->phy_gain << 6); phy_gain2 = phy_gain1; } else { phy_gain1 = 0x4040; phy_gain2 = 0x4000; } PHY_FILT_SETBITS(mac, 0x4a0, 0xbfbf, phy_gain1); PHY_FILT_SETBITS(mac, 0x4a1, 0xbfbf, phy_gain1); PHY_FILT_SETBITS(mac, 0x4a2, 0xbfbf, phy_gain2); } bwi_mac_dummy_xmit(mac); } static void bwi_phy_clear_state(struct bwi_phy *phy) { phy->phy_flags &= ~BWI_CLEAR_PHY_FLAGS; } /* RF */ static int16_t bwi_nrssi_11g(struct bwi_mac *mac) { int16_t val; #define NRSSI_11G_MASK 0x3f00 val = (int16_t)__SHIFTOUT(PHY_READ(mac, 0x47f), NRSSI_11G_MASK); if (val >= 32) val -= 64; return (val); #undef NRSSI_11G_MASK } static struct bwi_rf_lo * bwi_get_rf_lo(struct bwi_mac *mac, uint16_t rf_atten, uint16_t bbp_atten) { int n; n = rf_atten + (14 * (bbp_atten / 2)); KASSERT(n < BWI_RFLO_MAX); return (&mac->mac_rf.rf_lo[n]); } static int bwi_rf_lo_isused(struct bwi_mac *mac, const struct bwi_rf_lo *lo) { struct bwi_rf *rf = &mac->mac_rf; int idx; idx = lo - rf->rf_lo; KASSERT(idx >= 0 && idx < BWI_RFLO_MAX); return (isset(rf->rf_lo_used, idx)); } static void bwi_rf_write(struct bwi_mac *mac, uint16_t ctrl, uint16_t data) { struct bwi_softc *sc = mac->mac_sc; CSR_WRITE_2(sc, BWI_RF_CTRL, ctrl); CSR_WRITE_2(sc, BWI_RF_DATA_LO, data); } static uint16_t bwi_rf_read(struct bwi_mac *mac, uint16_t ctrl) { struct bwi_rf *rf = &mac->mac_rf; struct bwi_softc *sc = mac->mac_sc; ctrl |= rf->rf_ctrl_rd; if (rf->rf_ctrl_adj) { /* XXX */ if (ctrl < 0x70) ctrl += 0x80; else if (ctrl < 0x80) ctrl += 0x70; } CSR_WRITE_2(sc, BWI_RF_CTRL, ctrl); return (CSR_READ_2(sc, BWI_RF_DATA_LO)); } static int bwi_rf_attach(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct bwi_phy *phy = &mac->mac_phy; struct bwi_rf *rf = &mac->mac_rf; uint16_t type, manu; uint8_t rev; /* * Get RF manufacture/type/revision */ if (sc->sc_bbp_id == BWI_BBPID_BCM4317) { /* * Fake a BCM2050 RF */ manu = BWI_RF_MANUFACT_BCM; type = BWI_RF_T_BCM2050; if (sc->sc_bbp_rev == 0) rev = 3; else if (sc->sc_bbp_rev == 1) rev = 4; else rev = 5; } else { uint32_t val; CSR_WRITE_2(sc, BWI_RF_CTRL, BWI_RF_CTRL_RFINFO); val = CSR_READ_2(sc, BWI_RF_DATA_HI); val <<= 16; CSR_WRITE_2(sc, BWI_RF_CTRL, BWI_RF_CTRL_RFINFO); val |= CSR_READ_2(sc, BWI_RF_DATA_LO); manu = __SHIFTOUT(val, BWI_RFINFO_MANUFACT_MASK); type = __SHIFTOUT(val, BWI_RFINFO_TYPE_MASK); rev = __SHIFTOUT(val, BWI_RFINFO_REV_MASK); } aprint_normal_dev(sc->sc_dev, "RF manu 0x%03x, type 0x%04x, rev %u\n", manu, type, rev); /* * Verify whether the RF is supported */ rf->rf_ctrl_rd = 0; rf->rf_ctrl_adj = 0; switch (phy->phy_mode) { case IEEE80211_MODE_11A: if (manu != BWI_RF_MANUFACT_BCM || type != BWI_RF_T_BCM2060 || rev != 1) { aprint_error_dev(sc->sc_dev, "only BCM2060 rev 1 RF is supported for" " 11A PHY\n"); return (ENXIO); } rf->rf_ctrl_rd = BWI_RF_CTRL_RD_11A; rf->rf_on = bwi_rf_on_11a; rf->rf_off = bwi_rf_off_11a; rf->rf_calc_rssi = bwi_rf_calc_rssi_bcm2060; break; case IEEE80211_MODE_11B: if (type == BWI_RF_T_BCM2050) { rf->rf_ctrl_rd = BWI_RF_CTRL_RD_11BG; rf->rf_calc_rssi = bwi_rf_calc_rssi_bcm2050; } else if (type == BWI_RF_T_BCM2053) { rf->rf_ctrl_adj = 1; rf->rf_calc_rssi = bwi_rf_calc_rssi_bcm2053; } else { aprint_error_dev(sc->sc_dev, "only BCM2050/BCM2053 RF is supported for" " 11B phy\n"); return (ENXIO); } rf->rf_on = bwi_rf_on_11bg; rf->rf_off = bwi_rf_off_11bg; rf->rf_calc_nrssi_slope = bwi_rf_calc_nrssi_slope_11b; rf->rf_set_nrssi_thr = bwi_rf_set_nrssi_thr_11b; if (phy->phy_rev == 6) rf->rf_lo_update = bwi_rf_lo_update_11g; else rf->rf_lo_update = bwi_rf_lo_update_11b; break; case IEEE80211_MODE_11G: if (type != BWI_RF_T_BCM2050) { aprint_error_dev(sc->sc_dev, "only BCM2050 RF is supported for" " 11G PHY\n"); return (ENXIO); } rf->rf_ctrl_rd = BWI_RF_CTRL_RD_11BG; rf->rf_on = bwi_rf_on_11bg; if (mac->mac_rev >= 5) rf->rf_off = bwi_rf_off_11g_rev5; else rf->rf_off = bwi_rf_off_11bg; rf->rf_calc_nrssi_slope = bwi_rf_calc_nrssi_slope_11g; rf->rf_set_nrssi_thr = bwi_rf_set_nrssi_thr_11g; rf->rf_calc_rssi = bwi_rf_calc_rssi_bcm2050; rf->rf_lo_update = bwi_rf_lo_update_11g; break; default: aprint_error_dev(sc->sc_dev, "unsupported PHY mode\n"); return (ENXIO); } rf->rf_type = type; rf->rf_rev = rev; rf->rf_manu = manu; rf->rf_curchan = IEEE80211_CHAN_ANY; rf->rf_ant_mode = BWI_ANT_MODE_AUTO; return (0); } static void bwi_rf_set_chan(struct bwi_mac *mac, uint chan, int work_around) { struct bwi_softc *sc = mac->mac_sc; if (chan == IEEE80211_CHAN_ANY) return; MOBJ_WRITE_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_CHAN, chan); /* TODO: 11A */ if (work_around) bwi_rf_workaround(mac, chan); CSR_WRITE_2(sc, BWI_RF_CHAN, BWI_RF_2GHZ_CHAN(chan)); if (chan == 14) { if (sc->sc_locale == BWI_SPROM_LOCALE_JAPAN) HFLAGS_CLRBITS(mac, BWI_HFLAG_NOT_JAPAN); else HFLAGS_SETBITS(mac, BWI_HFLAG_NOT_JAPAN); CSR_SETBITS_2(sc, BWI_RF_CHAN_EX, (1 << 11)); /* XXX */ } else { CSR_CLRBITS_2(sc, BWI_RF_CHAN_EX, 0x840); /* XXX */ } DELAY(8000); /* DELAY(2000); */ mac->mac_rf.rf_curchan = chan; } static void bwi_rf_get_gains(struct bwi_mac *mac) { #define SAVE_PHY_MAX 15 #define SAVE_RF_MAX 3 static const uint16_t save_rf_regs[SAVE_RF_MAX] = { 0x52, 0x43, 0x7a }; static const uint16_t save_phy_regs[SAVE_PHY_MAX] = { 0x0429, 0x0001, 0x0811, 0x0812, 0x0814, 0x0815, 0x005a, 0x0059, 0x0058, 0x000a, 0x0003, 0x080f, 0x0810, 0x002b, 0x0015 }; struct bwi_phy *phy = &mac->mac_phy; struct bwi_rf *rf = &mac->mac_rf; uint16_t save_phy[SAVE_PHY_MAX]; uint16_t save_rf[SAVE_RF_MAX]; uint16_t trsw; int i, j, loop1_max, loop1, loop2; /* * Save PHY/RF registers for later restoration */ for (i = 0; i < SAVE_PHY_MAX; ++i) save_phy[i] = PHY_READ(mac, save_phy_regs[i]); PHY_READ(mac, 0x2d); /* dummy read */ for (i = 0; i < SAVE_RF_MAX; ++i) save_rf[i] = RF_READ(mac, save_rf_regs[i]); PHY_CLRBITS(mac, 0x429, 0xc000); PHY_SETBITS(mac, 0x1, 0x8000); PHY_SETBITS(mac, 0x811, 0x2); PHY_CLRBITS(mac, 0x812, 0x2); PHY_SETBITS(mac, 0x811, 0x1); PHY_CLRBITS(mac, 0x812, 0x1); PHY_SETBITS(mac, 0x814, 0x1); PHY_CLRBITS(mac, 0x815, 0x1); PHY_SETBITS(mac, 0x814, 0x2); PHY_CLRBITS(mac, 0x815, 0x2); PHY_SETBITS(mac, 0x811, 0xc); PHY_SETBITS(mac, 0x812, 0xc); PHY_SETBITS(mac, 0x811, 0x30); PHY_FILT_SETBITS(mac, 0x812, 0xffcf, 0x10); PHY_WRITE(mac, 0x5a, 0x780); PHY_WRITE(mac, 0x59, 0xc810); PHY_WRITE(mac, 0x58, 0xd); PHY_SETBITS(mac, 0xa, 0x2000); PHY_SETBITS(mac, 0x814, 0x4); PHY_CLRBITS(mac, 0x815, 0x4); PHY_FILT_SETBITS(mac, 0x3, 0xff9f, 0x40); if (rf->rf_rev == 8) { loop1_max = 15; RF_WRITE(mac, 0x43, loop1_max); } else { loop1_max = 9; RF_WRITE(mac, 0x52, 0x0); RF_FILT_SETBITS(mac, 0x43, 0xfff0, loop1_max); } bwi_phy_set_bbp_atten(mac, 11); if (phy->phy_rev >= 3) PHY_WRITE(mac, 0x80f, 0xc020); else PHY_WRITE(mac, 0x80f, 0x8020); PHY_WRITE(mac, 0x810, 0); PHY_FILT_SETBITS(mac, 0x2b, 0xffc0, 0x1); PHY_FILT_SETBITS(mac, 0x2b, 0xc0ff, 0x800); PHY_SETBITS(mac, 0x811, 0x100); PHY_CLRBITS(mac, 0x812, 0x3000); if ((mac->mac_sc->sc_card_flags & BWI_CARD_F_EXT_LNA) && phy->phy_rev >= 7) { PHY_SETBITS(mac, 0x811, 0x800); PHY_SETBITS(mac, 0x812, 0x8000); } RF_CLRBITS(mac, 0x7a, 0xff08); /* * Find out 'loop1/loop2', which will be used to calculate * max loopback gain later */ j = 0; for (i = 0; i < loop1_max; ++i) { for (j = 0; j < 16; ++j) { RF_WRITE(mac, 0x43, i); if (bwi_rf_gain_max_reached(mac, j)) goto loop1_exit; } } loop1_exit: loop1 = i; loop2 = j; /* * Find out 'trsw', which will be used to calculate * TRSW(TX/RX switch) RX gain later */ if (loop2 >= 8) { PHY_SETBITS(mac, 0x812, 0x30); trsw = 0x1b; for (i = loop2 - 8; i < 16; ++i) { trsw -= 3; if (bwi_rf_gain_max_reached(mac, i)) break; } } else { trsw = 0x18; } /* * Restore saved PHY/RF registers */ /* First 4 saved PHY registers need special processing */ for (i = 4; i < SAVE_PHY_MAX; ++i) PHY_WRITE(mac, save_phy_regs[i], save_phy[i]); bwi_phy_set_bbp_atten(mac, mac->mac_tpctl.bbp_atten); for (i = 0; i < SAVE_RF_MAX; ++i) RF_WRITE(mac, save_rf_regs[i], save_rf[i]); PHY_WRITE(mac, save_phy_regs[2], save_phy[2] | 0x3); DELAY(10); PHY_WRITE(mac, save_phy_regs[2], save_phy[2]); PHY_WRITE(mac, save_phy_regs[3], save_phy[3]); PHY_WRITE(mac, save_phy_regs[0], save_phy[0]); PHY_WRITE(mac, save_phy_regs[1], save_phy[1]); /* * Calculate gains */ rf->rf_lo_gain = (loop2 * 6) - (loop1 * 4) - 11; rf->rf_rx_gain = trsw * 2; DPRINTF(mac->mac_sc, BWI_DBG_RF | BWI_DBG_INIT, "lo gain: %u, rx gain: %u\n", rf->rf_lo_gain, rf->rf_rx_gain); #undef SAVE_RF_MAX #undef SAVE_PHY_MAX } static void bwi_rf_init(struct bwi_mac *mac) { struct bwi_rf *rf = &mac->mac_rf; if (rf->rf_type == BWI_RF_T_BCM2060) { /* TODO: 11A */ } else { if (rf->rf_flags & BWI_RF_F_INITED) RF_WRITE(mac, 0x78, rf->rf_calib); else bwi_rf_init_bcm2050(mac); } } static void bwi_rf_off_11a(struct bwi_mac *mac) { RF_WRITE(mac, 0x4, 0xff); RF_WRITE(mac, 0x5, 0xfb); PHY_SETBITS(mac, 0x10, 0x8); PHY_SETBITS(mac, 0x11, 0x8); PHY_WRITE(mac, 0x15, 0xaa00); } static void bwi_rf_off_11bg(struct bwi_mac *mac) { PHY_WRITE(mac, 0x15, 0xaa00); } static void bwi_rf_off_11g_rev5(struct bwi_mac *mac) { PHY_SETBITS(mac, 0x811, 0x8c); PHY_CLRBITS(mac, 0x812, 0x8c); } static void bwi_rf_workaround(struct bwi_mac *mac, uint chan) { struct bwi_softc *sc = mac->mac_sc; struct bwi_rf *rf = &mac->mac_rf; if (chan == IEEE80211_CHAN_ANY) { aprint_error_dev(sc->sc_dev, "%s invalid channel!\n", __func__); return; } if (rf->rf_type != BWI_RF_T_BCM2050 || rf->rf_rev >= 6) return; if (chan <= 10) CSR_WRITE_2(sc, BWI_RF_CHAN, BWI_RF_2GHZ_CHAN(chan + 4)); else CSR_WRITE_2(sc, BWI_RF_CHAN, BWI_RF_2GHZ_CHAN(1)); DELAY(1000); CSR_WRITE_2(sc, BWI_RF_CHAN, BWI_RF_2GHZ_CHAN(chan)); } static struct bwi_rf_lo * bwi_rf_lo_find(struct bwi_mac *mac, const struct bwi_tpctl *tpctl) { uint16_t rf_atten, bbp_atten; int remap_rf_atten; remap_rf_atten = 1; if (tpctl == NULL) { bbp_atten = 2; rf_atten = 3; } else { if (tpctl->tp_ctrl1 == 3) remap_rf_atten = 0; bbp_atten = tpctl->bbp_atten; rf_atten = tpctl->rf_atten; if (bbp_atten > 6) bbp_atten = 6; } if (remap_rf_atten) { #define MAP_MAX 10 static const uint16_t map[MAP_MAX] = { 11, 10, 11, 12, 13, 12, 13, 12, 13, 12 }; #if 0 KASSERT(rf_atten < MAP_MAX); rf_atten = map[rf_atten]; #else if (rf_atten >= MAP_MAX) { rf_atten = 0; /* XXX */ } else { rf_atten = map[rf_atten]; } #endif #undef MAP_MAX } return (bwi_get_rf_lo(mac, rf_atten, bbp_atten)); } static void bwi_rf_lo_adjust(struct bwi_mac *mac, const struct bwi_tpctl *tpctl) { const struct bwi_rf_lo *lo; lo = bwi_rf_lo_find(mac, tpctl); RF_LO_WRITE(mac, lo); } static void bwi_rf_lo_write(struct bwi_mac *mac, const struct bwi_rf_lo *lo) { uint16_t val; val = (uint8_t)lo->ctrl_lo; val |= ((uint8_t)lo->ctrl_hi) << 8; PHY_WRITE(mac, BWI_PHYR_RF_LO, val); } static int bwi_rf_gain_max_reached(struct bwi_mac *mac, int idx) { PHY_FILT_SETBITS(mac, 0x812, 0xf0ff, idx << 8); PHY_FILT_SETBITS(mac, 0x15, 0xfff, 0xa000); PHY_SETBITS(mac, 0x15, 0xf000); DELAY(20); return ((PHY_READ(mac, 0x2d) >= 0xdfc)); } /* XXX use bitmap array */ static uint16_t bwi_bitswap4(uint16_t val) { uint16_t ret; ret = (val & 0x8) >> 3; ret |= (val & 0x4) >> 1; ret |= (val & 0x2) << 1; ret |= (val & 0x1) << 3; return (ret); } static uint16_t bwi_phy812_value(struct bwi_mac *mac, uint16_t lpd) { struct bwi_softc *sc = mac->mac_sc; struct bwi_phy *phy = &mac->mac_phy; struct bwi_rf *rf = &mac->mac_rf; uint16_t lo_gain, ext_lna, loop; if ((phy->phy_flags & BWI_PHY_F_LINKED) == 0) return (0); lo_gain = rf->rf_lo_gain; if (rf->rf_rev == 8) lo_gain += 0x3e; else lo_gain += 0x26; if (lo_gain >= 0x46) { lo_gain -= 0x46; ext_lna = 0x3000; } else if (lo_gain >= 0x3a) { lo_gain -= 0x3a; ext_lna = 0x1000; } else if (lo_gain >= 0x2e) { lo_gain -= 0x2e; ext_lna = 0x2000; } else { lo_gain -= 0x10; ext_lna = 0; } for (loop = 0; loop < 16; ++loop) { lo_gain -= (6 * loop); if (lo_gain < 6) break; } if (phy->phy_rev >= 7 && (sc->sc_card_flags & BWI_CARD_F_EXT_LNA)) { if (ext_lna) ext_lna |= 0x8000; ext_lna |= (loop << 8); switch (lpd) { case 0x011: return (0x8f92); case 0x001: return (0x8092 | ext_lna); case 0x101: return (0x2092 | ext_lna); case 0x100: return (0x2093 | ext_lna); default: panic("unsupported lpd\n"); } } else { ext_lna |= (loop << 8); switch (lpd) { case 0x011: return (0xf92); case 0x001: case 0x101: return (0x92 | ext_lna); case 0x100: return (0x93 | ext_lna); default: panic("unsupported lpd\n"); } } panic("never reached\n"); return (0); } static void bwi_rf_init_bcm2050(struct bwi_mac *mac) { #define SAVE_RF_MAX 3 #define SAVE_PHY_COMM_MAX 4 #define SAVE_PHY_11G_MAX 6 static const uint16_t save_rf_regs[SAVE_RF_MAX] = { 0x0043, 0x0051, 0x0052 }; static const uint16_t save_phy_regs_comm[SAVE_PHY_COMM_MAX] = { 0x0015, 0x005a, 0x0059, 0x0058 }; static const uint16_t save_phy_regs_11g[SAVE_PHY_11G_MAX] = { 0x0811, 0x0812, 0x0814, 0x0815, 0x0429, 0x0802 }; uint16_t save_rf[SAVE_RF_MAX]; uint16_t save_phy_comm[SAVE_PHY_COMM_MAX]; uint16_t save_phy_11g[SAVE_PHY_11G_MAX]; uint16_t phyr_35, phyr_30 = 0, rfr_78, phyr_80f = 0, phyr_810 = 0; uint16_t bphy_ctrl = 0, bbp_atten, rf_chan_ex; uint16_t phy812_val; uint16_t calib; uint32_t test_lim, test; struct bwi_softc *sc = mac->mac_sc; struct bwi_phy *phy = &mac->mac_phy; struct bwi_rf *rf = &mac->mac_rf; int i; /* * Save registers for later restoring */ for (i = 0; i < SAVE_RF_MAX; ++i) save_rf[i] = RF_READ(mac, save_rf_regs[i]); for (i = 0; i < SAVE_PHY_COMM_MAX; ++i) save_phy_comm[i] = PHY_READ(mac, save_phy_regs_comm[i]); if (phy->phy_mode == IEEE80211_MODE_11B) { phyr_30 = PHY_READ(mac, 0x30); bphy_ctrl = CSR_READ_2(sc, BWI_BPHY_CTRL); PHY_WRITE(mac, 0x30, 0xff); CSR_WRITE_2(sc, BWI_BPHY_CTRL, 0x3f3f); } else if ((phy->phy_flags & BWI_PHY_F_LINKED) || phy->phy_rev >= 2) { for (i = 0; i < SAVE_PHY_11G_MAX; ++i) { save_phy_11g[i] = PHY_READ(mac, save_phy_regs_11g[i]); } PHY_SETBITS(mac, 0x814, 0x3); PHY_CLRBITS(mac, 0x815, 0x3); PHY_CLRBITS(mac, 0x429, 0x8000); PHY_CLRBITS(mac, 0x802, 0x3); phyr_80f = PHY_READ(mac, 0x80f); phyr_810 = PHY_READ(mac, 0x810); if (phy->phy_rev >= 3) PHY_WRITE(mac, 0x80f, 0xc020); else PHY_WRITE(mac, 0x80f, 0x8020); PHY_WRITE(mac, 0x810, 0); phy812_val = bwi_phy812_value(mac, 0x011); PHY_WRITE(mac, 0x812, phy812_val); if (phy->phy_rev < 7 || (sc->sc_card_flags & BWI_CARD_F_EXT_LNA) == 0) PHY_WRITE(mac, 0x811, 0x1b3); else PHY_WRITE(mac, 0x811, 0x9b3); } CSR_SETBITS_2(sc, BWI_RF_ANTDIV, 0x8000); phyr_35 = PHY_READ(mac, 0x35); PHY_CLRBITS(mac, 0x35, 0x80); bbp_atten = CSR_READ_2(sc, BWI_BBP_ATTEN); rf_chan_ex = CSR_READ_2(sc, BWI_RF_CHAN_EX); if (phy->phy_version == 0) { CSR_WRITE_2(sc, BWI_BBP_ATTEN, 0x122); } else { if (phy->phy_version >= 2) PHY_FILT_SETBITS(mac, 0x3, 0xffbf, 0x40); CSR_SETBITS_2(sc, BWI_RF_CHAN_EX, 0x2000); } calib = bwi_rf_calibval(mac); if (phy->phy_mode == IEEE80211_MODE_11B) RF_WRITE(mac, 0x78, 0x26); if ((phy->phy_flags & BWI_PHY_F_LINKED) || phy->phy_rev >= 2) { phy812_val = bwi_phy812_value(mac, 0x011); PHY_WRITE(mac, 0x812, phy812_val); } PHY_WRITE(mac, 0x15, 0xbfaf); PHY_WRITE(mac, 0x2b, 0x1403); if ((phy->phy_flags & BWI_PHY_F_LINKED) || phy->phy_rev >= 2) { phy812_val = bwi_phy812_value(mac, 0x001); PHY_WRITE(mac, 0x812, phy812_val); } PHY_WRITE(mac, 0x15, 0xbfa0); RF_SETBITS(mac, 0x51, 0x4); if (rf->rf_rev == 8) RF_WRITE(mac, 0x43, 0x1f); else { RF_WRITE(mac, 0x52, 0); RF_FILT_SETBITS(mac, 0x43, 0xfff0, 0x9); } test_lim = 0; PHY_WRITE(mac, 0x58, 0); for (i = 0; i < 16; ++i) { PHY_WRITE(mac, 0x5a, 0x480); PHY_WRITE(mac, 0x59, 0xc810); PHY_WRITE(mac, 0x58, 0xd); if ((phy->phy_flags & BWI_PHY_F_LINKED) || phy->phy_rev >= 2) { phy812_val = bwi_phy812_value(mac, 0x101); PHY_WRITE(mac, 0x812, phy812_val); } PHY_WRITE(mac, 0x15, 0xafb0); DELAY(10); if ((phy->phy_flags & BWI_PHY_F_LINKED) || phy->phy_rev >= 2) { phy812_val = bwi_phy812_value(mac, 0x101); PHY_WRITE(mac, 0x812, phy812_val); } PHY_WRITE(mac, 0x15, 0xefb0); DELAY(10); if ((phy->phy_flags & BWI_PHY_F_LINKED) || phy->phy_rev >= 2) { phy812_val = bwi_phy812_value(mac, 0x100); PHY_WRITE(mac, 0x812, phy812_val); } PHY_WRITE(mac, 0x15, 0xfff0); DELAY(20); test_lim += PHY_READ(mac, 0x2d); PHY_WRITE(mac, 0x58, 0); if ((phy->phy_flags & BWI_PHY_F_LINKED) || phy->phy_rev >= 2) { phy812_val = bwi_phy812_value(mac, 0x101); PHY_WRITE(mac, 0x812, phy812_val); } PHY_WRITE(mac, 0x15, 0xafb0); } ++test_lim; test_lim >>= 9; DELAY(10); test = 0; PHY_WRITE(mac, 0x58, 0); for (i = 0; i < 16; ++i) { int j; rfr_78 = (bwi_bitswap4(i) << 1) | 0x20; RF_WRITE(mac, 0x78, rfr_78); DELAY(10); /* NB: This block is slight different than the above one */ for (j = 0; j < 16; ++j) { PHY_WRITE(mac, 0x5a, 0xd80); PHY_WRITE(mac, 0x59, 0xc810); PHY_WRITE(mac, 0x58, 0xd); if ((phy->phy_flags & BWI_PHY_F_LINKED) || phy->phy_rev >= 2) { phy812_val = bwi_phy812_value(mac, 0x101); PHY_WRITE(mac, 0x812, phy812_val); } PHY_WRITE(mac, 0x15, 0xafb0); DELAY(10); if ((phy->phy_flags & BWI_PHY_F_LINKED) || phy->phy_rev >= 2) { phy812_val = bwi_phy812_value(mac, 0x101); PHY_WRITE(mac, 0x812, phy812_val); } PHY_WRITE(mac, 0x15, 0xefb0); DELAY(10); if ((phy->phy_flags & BWI_PHY_F_LINKED) || phy->phy_rev >= 2) { phy812_val = bwi_phy812_value(mac, 0x100); PHY_WRITE(mac, 0x812, phy812_val); } PHY_WRITE(mac, 0x15, 0xfff0); DELAY(10); test += PHY_READ(mac, 0x2d); PHY_WRITE(mac, 0x58, 0); if ((phy->phy_flags & BWI_PHY_F_LINKED) || phy->phy_rev >= 2) { phy812_val = bwi_phy812_value(mac, 0x101); PHY_WRITE(mac, 0x812, phy812_val); } PHY_WRITE(mac, 0x15, 0xafb0); } ++test; test >>= 8; if (test > test_lim) break; } if (i > 15) rf->rf_calib = rfr_78; else rf->rf_calib = calib; if (rf->rf_calib != 0xffff) { DPRINTF(sc, BWI_DBG_RF | BWI_DBG_INIT, "RF calibration value: 0x%04x\n", rf->rf_calib); rf->rf_flags |= BWI_RF_F_INITED; } /* * Restore trashes registers */ PHY_WRITE(mac, save_phy_regs_comm[0], save_phy_comm[0]); for (i = 0; i < SAVE_RF_MAX; ++i) { int pos = (i + 1) % SAVE_RF_MAX; RF_WRITE(mac, save_rf_regs[pos], save_rf[pos]); } for (i = 1; i < SAVE_PHY_COMM_MAX; ++i) PHY_WRITE(mac, save_phy_regs_comm[i], save_phy_comm[i]); CSR_WRITE_2(sc, BWI_BBP_ATTEN, bbp_atten); if (phy->phy_version != 0) CSR_WRITE_2(sc, BWI_RF_CHAN_EX, rf_chan_ex); PHY_WRITE(mac, 0x35, phyr_35); bwi_rf_workaround(mac, rf->rf_curchan); if (phy->phy_mode == IEEE80211_MODE_11B) { PHY_WRITE(mac, 0x30, phyr_30); CSR_WRITE_2(sc, BWI_BPHY_CTRL, bphy_ctrl); } else if ((phy->phy_flags & BWI_PHY_F_LINKED) || phy->phy_rev >= 2) { /* XXX Spec only says when PHY is linked (gmode) */ CSR_CLRBITS_2(sc, BWI_RF_ANTDIV, 0x8000); for (i = 0; i < SAVE_PHY_11G_MAX; ++i) { PHY_WRITE(mac, save_phy_regs_11g[i], save_phy_11g[i]); } PHY_WRITE(mac, 0x80f, phyr_80f); PHY_WRITE(mac, 0x810, phyr_810); } #undef SAVE_PHY_11G_MAX #undef SAVE_PHY_COMM_MAX #undef SAVE_RF_MAX } static uint16_t bwi_rf_calibval(struct bwi_mac *mac) { /* http://bcm-specs.sipsolutions.net/RCCTable */ static const uint16_t rf_calibvals[] = { 0x2, 0x3, 0x1, 0xf, 0x6, 0x7, 0x5, 0xf, 0xa, 0xb, 0x9, 0xf, 0xe, 0xf, 0xd, 0xf }; uint16_t val, calib; int idx; val = RF_READ(mac, BWI_RFR_BBP_ATTEN); idx = __SHIFTOUT(val, BWI_RFR_BBP_ATTEN_CALIB_IDX); KASSERT(idx < (int)(sizeof(rf_calibvals) / sizeof(rf_calibvals[0]))); calib = rf_calibvals[idx] << 1; if (val & BWI_RFR_BBP_ATTEN_CALIB_BIT) calib |= 0x1; calib |= 0x20; return (calib); } static int32_t _bwi_adjust_devide(int32_t num, int32_t den) { if (num < 0) return (num / den); else return ((num + den / 2) / den); } /* * http://bcm-specs.sipsolutions.net/TSSI_to_DBM_Table * "calculating table entries" */ static int bwi_rf_calc_txpower(int8_t *txpwr, uint8_t idx, const int16_t pa_params[]) { int32_t m1, m2, f, dbm; int i; m1 = _bwi_adjust_devide(16 * pa_params[0] + idx * pa_params[1], 32); m2 = imax(_bwi_adjust_devide(32768 + idx * pa_params[2], 256), 1); #define ITER_MAX 16 f = 256; for (i = 0; i < ITER_MAX; ++i) { int32_t q, d; q = _bwi_adjust_devide( f * 4096 - _bwi_adjust_devide(m2 * f, 16) * f, 2048); d = abs(q - f); f = q; if (d < 2) break; } if (i == ITER_MAX) return (EINVAL); #undef ITER_MAX dbm = _bwi_adjust_devide(m1 * f, 8192); if (dbm < -127) dbm = -127; else if (dbm > 128) dbm = 128; *txpwr = dbm; return (0); } static int bwi_rf_map_txpower(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct bwi_rf *rf = &mac->mac_rf; struct bwi_phy *phy = &mac->mac_phy; uint16_t sprom_ofs, val, mask; int16_t pa_params[3]; int error = 0, i, ant_gain, reg_txpower_max; #ifdef BWI_DEBUG int debug = sc->sc_debug & (BWI_DBG_RF | BWI_DBG_TXPOWER | BWI_DBG_ATTACH); #endif /* * Find out max TX power */ val = bwi_read_sprom(sc, BWI_SPROM_MAX_TXPWR); if (phy->phy_mode == IEEE80211_MODE_11A) { rf->rf_txpower_max = __SHIFTOUT(val, BWI_SPROM_MAX_TXPWR_MASK_11A); } else { rf->rf_txpower_max = __SHIFTOUT(val, BWI_SPROM_MAX_TXPWR_MASK_11BG); if ((sc->sc_card_flags & BWI_CARD_F_PA_GPIO9) && phy->phy_mode == IEEE80211_MODE_11G) rf->rf_txpower_max -= 3; } if (rf->rf_txpower_max <= 0) { aprint_error_dev(sc->sc_dev, "invalid max txpower in sprom\n"); rf->rf_txpower_max = 74; } DPRINTF(sc, BWI_DBG_RF | BWI_DBG_TXPOWER | BWI_DBG_ATTACH, "max txpower from sprom: %d dBm\n", rf->rf_txpower_max); /* * Find out region/domain max TX power, which is adjusted * by antenna gain and 1.5 dBm fluctuation as mentioned * in v3 spec. */ val = bwi_read_sprom(sc, BWI_SPROM_ANT_GAIN); if (phy->phy_mode == IEEE80211_MODE_11A) ant_gain = __SHIFTOUT(val, BWI_SPROM_ANT_GAIN_MASK_11A); else ant_gain = __SHIFTOUT(val, BWI_SPROM_ANT_GAIN_MASK_11BG); if (ant_gain == 0xff) { /* XXX why this always invalid? */ aprint_error_dev(sc->sc_dev, "invalid antenna gain in sprom\n"); ant_gain = 2; } ant_gain *= 4; DPRINTF(sc, BWI_DBG_RF | BWI_DBG_TXPOWER | BWI_DBG_ATTACH, "ant gain %d dBm\n", ant_gain); reg_txpower_max = 90 - ant_gain - 6; /* XXX magic number */ DPRINTF(sc, BWI_DBG_RF | BWI_DBG_TXPOWER | BWI_DBG_ATTACH, "region/domain max txpower %d dBm\n", reg_txpower_max); /* * Force max TX power within region/domain TX power limit */ if (rf->rf_txpower_max > reg_txpower_max) rf->rf_txpower_max = reg_txpower_max; DPRINTF(sc, BWI_DBG_RF | BWI_DBG_TXPOWER | BWI_DBG_ATTACH, "max txpower %d dBm\n", rf->rf_txpower_max); /* * Create TSSI to TX power mapping */ if (sc->sc_bbp_id == BWI_BBPID_BCM4301 && rf->rf_type != BWI_RF_T_BCM2050) { rf->rf_idle_tssi0 = BWI_DEFAULT_IDLE_TSSI; memcpy(rf->rf_txpower_map0, bwi_txpower_map_11b, sizeof(rf->rf_txpower_map0)); goto back; } #define IS_VALID_PA_PARAM(p) ((p) != 0 && (p) != -1) /* * Extract PA parameters */ if (phy->phy_mode == IEEE80211_MODE_11A) sprom_ofs = BWI_SPROM_PA_PARAM_11A; else sprom_ofs = BWI_SPROM_PA_PARAM_11BG; for (i = 0; i < __arraycount(pa_params); ++i) pa_params[i] = (int16_t)bwi_read_sprom(sc, sprom_ofs + (i * 2)); for (i = 0; i < __arraycount(pa_params); ++i) { /* * If one of the PA parameters from SPROM is not valid, * fall back to the default values, if there are any. */ if (!IS_VALID_PA_PARAM(pa_params[i])) { const int8_t *txpower_map; if (phy->phy_mode == IEEE80211_MODE_11A) { aprint_error_dev(sc->sc_dev, "no tssi2dbm table for 11a PHY\n"); return (ENXIO); } if (phy->phy_mode == IEEE80211_MODE_11G) { DPRINTF(sc, BWI_DBG_RF | BWI_DBG_TXPOWER | BWI_DBG_ATTACH, "use default 11g TSSI map\n"); txpower_map = bwi_txpower_map_11g; } else { DPRINTF(sc, BWI_DBG_RF | BWI_DBG_TXPOWER | BWI_DBG_ATTACH, "use default 11b TSSI map\n"); txpower_map = bwi_txpower_map_11b; } rf->rf_idle_tssi0 = BWI_DEFAULT_IDLE_TSSI; memcpy(rf->rf_txpower_map0, txpower_map, sizeof(rf->rf_txpower_map0)); goto back; } } /* * All of the PA parameters from SPROM are valid. */ /* * Extract idle TSSI from SPROM. */ val = bwi_read_sprom(sc, BWI_SPROM_IDLE_TSSI); DPRINTF(sc, BWI_DBG_RF | BWI_DBG_TXPOWER | BWI_DBG_ATTACH, "sprom idle tssi: 0x%04x\n", val); if (phy->phy_mode == IEEE80211_MODE_11A) mask = BWI_SPROM_IDLE_TSSI_MASK_11A; else mask = BWI_SPROM_IDLE_TSSI_MASK_11BG; rf->rf_idle_tssi0 = (int)__SHIFTOUT(val, mask); if (!IS_VALID_PA_PARAM(rf->rf_idle_tssi0)) rf->rf_idle_tssi0 = 62; #undef IS_VALID_PA_PARAM /* * Calculate TX power map, which is indexed by TSSI */ DPRINTF(sc, BWI_DBG_RF | BWI_DBG_TXPOWER | BWI_DBG_ATTACH, "TSSI-TX power map:\n"); for (i = 0; i < BWI_TSSI_MAX; ++i) { error = bwi_rf_calc_txpower(&rf->rf_txpower_map0[i], i, pa_params); if (error) { aprint_error_dev(sc->sc_dev, "bwi_rf_calc_txpower failed\n"); break; } #ifdef BWI_DEBUG if (debug) { if (i % 8 == 0) { if (i != 0) aprint_debug("\n"); aprint_debug_dev(sc->sc_dev, ""); } aprint_debug(" %d", rf->rf_txpower_map0[i]); } #endif } #ifdef BWI_DEBUG if (debug) aprint_debug("\n"); #endif back: DPRINTF(sc, BWI_DBG_RF | BWI_DBG_TXPOWER | BWI_DBG_ATTACH, "idle tssi0: %d\n", rf->rf_idle_tssi0); return (error); } static void bwi_rf_lo_update_11g(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct ifnet *ifp = &sc->sc_if; struct bwi_rf *rf = &mac->mac_rf; struct bwi_phy *phy = &mac->mac_phy; struct bwi_tpctl *tpctl = &mac->mac_tpctl; struct rf_saveregs regs; uint16_t ant_div, chan_ex; uint8_t devi_ctrl; uint orig_chan; DPRINTF(sc, BWI_DBG_RF | BWI_DBG_INIT, "%s enter\n", __func__); /* * Save RF/PHY registers for later restoration */ orig_chan = rf->rf_curchan; memset(®s, 0, sizeof(regs)); if (phy->phy_flags & BWI_PHY_F_LINKED) { SAVE_PHY_REG(mac, ®s, 429); SAVE_PHY_REG(mac, ®s, 802); PHY_WRITE(mac, 0x429, regs.phy_429 & 0x7fff); PHY_WRITE(mac, 0x802, regs.phy_802 & 0xfffc); } ant_div = CSR_READ_2(sc, BWI_RF_ANTDIV); CSR_WRITE_2(sc, BWI_RF_ANTDIV, ant_div | 0x8000); chan_ex = CSR_READ_2(sc, BWI_RF_CHAN_EX); SAVE_PHY_REG(mac, ®s, 15); SAVE_PHY_REG(mac, ®s, 2a); SAVE_PHY_REG(mac, ®s, 35); SAVE_PHY_REG(mac, ®s, 60); SAVE_RF_REG(mac, ®s, 43); SAVE_RF_REG(mac, ®s, 7a); SAVE_RF_REG(mac, ®s, 52); if (phy->phy_flags & BWI_PHY_F_LINKED) { SAVE_PHY_REG(mac, ®s, 811); SAVE_PHY_REG(mac, ®s, 812); SAVE_PHY_REG(mac, ®s, 814); SAVE_PHY_REG(mac, ®s, 815); } /* Force to channel 6 */ bwi_rf_set_chan(mac, 6, 0); if (phy->phy_flags & BWI_PHY_F_LINKED) { PHY_WRITE(mac, 0x429, regs.phy_429 & 0x7fff); PHY_WRITE(mac, 0x802, regs.phy_802 & 0xfffc); bwi_mac_dummy_xmit(mac); } RF_WRITE(mac, 0x43, 0x6); bwi_phy_set_bbp_atten(mac, 2); CSR_WRITE_2(sc, BWI_RF_CHAN_EX, 0); PHY_WRITE(mac, 0x2e, 0x7f); PHY_WRITE(mac, 0x80f, 0x78); PHY_WRITE(mac, 0x35, regs.phy_35 & 0xff7f); RF_WRITE(mac, 0x7a, regs.rf_7a & 0xfff0); PHY_WRITE(mac, 0x2b, 0x203); PHY_WRITE(mac, 0x2a, 0x8a3); if (phy->phy_flags & BWI_PHY_F_LINKED) { PHY_WRITE(mac, 0x814, regs.phy_814 | 0x3); PHY_WRITE(mac, 0x815, regs.phy_815 & 0xfffc); PHY_WRITE(mac, 0x811, 0x1b3); PHY_WRITE(mac, 0x812, 0xb2); } if ((ifp->if_flags & IFF_RUNNING) == 0) tpctl->tp_ctrl2 = bwi_rf_get_tp_ctrl2(mac); PHY_WRITE(mac, 0x80f, 0x8078); /* * Measure all RF LO */ devi_ctrl = _bwi_rf_lo_update_11g(mac, regs.rf_7a); /* * Restore saved RF/PHY registers */ if (phy->phy_flags & BWI_PHY_F_LINKED) { PHY_WRITE(mac, 0x15, 0xe300); PHY_WRITE(mac, 0x812, (devi_ctrl << 8) | 0xa0); DELAY(5); PHY_WRITE(mac, 0x812, (devi_ctrl << 8) | 0xa2); DELAY(2); PHY_WRITE(mac, 0x812, (devi_ctrl << 8) | 0xa3); } else PHY_WRITE(mac, 0x15, devi_ctrl | 0xefa0); if ((ifp->if_flags & IFF_RUNNING) == 0) tpctl = NULL; bwi_rf_lo_adjust(mac, tpctl); PHY_WRITE(mac, 0x2e, 0x807f); if (phy->phy_flags & BWI_PHY_F_LINKED) PHY_WRITE(mac, 0x2f, 0x202); else PHY_WRITE(mac, 0x2f, 0x101); CSR_WRITE_2(sc, BWI_RF_CHAN_EX, chan_ex); RESTORE_PHY_REG(mac, ®s, 15); RESTORE_PHY_REG(mac, ®s, 2a); RESTORE_PHY_REG(mac, ®s, 35); RESTORE_PHY_REG(mac, ®s, 60); RESTORE_RF_REG(mac, ®s, 43); RESTORE_RF_REG(mac, ®s, 7a); regs.rf_52 &= 0xf0; regs.rf_52 |= (RF_READ(mac, 0x52) & 0xf); RF_WRITE(mac, 0x52, regs.rf_52); CSR_WRITE_2(sc, BWI_RF_ANTDIV, ant_div); if (phy->phy_flags & BWI_PHY_F_LINKED) { RESTORE_PHY_REG(mac, ®s, 811); RESTORE_PHY_REG(mac, ®s, 812); RESTORE_PHY_REG(mac, ®s, 814); RESTORE_PHY_REG(mac, ®s, 815); RESTORE_PHY_REG(mac, ®s, 429); RESTORE_PHY_REG(mac, ®s, 802); } bwi_rf_set_chan(mac, orig_chan, 1); } static uint32_t bwi_rf_lo_devi_measure(struct bwi_mac *mac, uint16_t ctrl) { struct bwi_phy *phy = &mac->mac_phy; uint32_t devi = 0; int i; if (phy->phy_flags & BWI_PHY_F_LINKED) ctrl <<= 8; for (i = 0; i < 8; ++i) { if (phy->phy_flags & BWI_PHY_F_LINKED) { PHY_WRITE(mac, 0x15, 0xe300); PHY_WRITE(mac, 0x812, ctrl | 0xb0); DELAY(5); PHY_WRITE(mac, 0x812, ctrl | 0xb2); DELAY(2); PHY_WRITE(mac, 0x812, ctrl | 0xb3); DELAY(4); PHY_WRITE(mac, 0x15, 0xf300); } else { PHY_WRITE(mac, 0x15, ctrl | 0xefa0); DELAY(2); PHY_WRITE(mac, 0x15, ctrl | 0xefe0); DELAY(4); PHY_WRITE(mac, 0x15, ctrl | 0xffe0); } DELAY(8); devi += PHY_READ(mac, 0x2d); } return (devi); } static uint16_t bwi_rf_get_tp_ctrl2(struct bwi_mac *mac) { uint32_t devi_min; uint16_t tp_ctrl2 = 0; int i; RF_WRITE(mac, 0x52, 0); DELAY(10); devi_min = bwi_rf_lo_devi_measure(mac, 0); for (i = 0; i < 16; ++i) { uint32_t devi; RF_WRITE(mac, 0x52, i); DELAY(10); devi = bwi_rf_lo_devi_measure(mac, 0); if (devi < devi_min) { devi_min = devi; tp_ctrl2 = i; } } return (tp_ctrl2); } static uint8_t _bwi_rf_lo_update_11g(struct bwi_mac *mac, uint16_t orig_rf7a) { #define RF_ATTEN_LISTSZ 14 #define BBP_ATTEN_MAX 4 /* half */ static const int rf_atten_list[RF_ATTEN_LISTSZ] = { 3, 1, 5, 7, 9, 2, 0, 4, 6, 8, 1, 2, 3, 4 }; static const int rf_atten_init_list[RF_ATTEN_LISTSZ] = { 0, 3, 1, 5, 7, 3, 2, 0, 4, 6, -1, -1, -1, -1 }; static const int rf_lo_measure_order[RF_ATTEN_LISTSZ] = { 3, 1, 5, 7, 9, 2, 0, 4, 6, 8, 10, 11, 12, 13 }; struct ifnet *ifp = &mac->mac_sc->sc_if; struct bwi_rf_lo lo_save, *lo; uint8_t devi_ctrl = 0; int idx, adj_rf7a = 0; memset(&lo_save, 0, sizeof(lo_save)); for (idx = 0; idx < RF_ATTEN_LISTSZ; ++idx) { int init_rf_atten = rf_atten_init_list[idx]; int rf_atten = rf_atten_list[idx]; int bbp_atten; for (bbp_atten = 0; bbp_atten < BBP_ATTEN_MAX; ++bbp_atten) { uint16_t tp_ctrl2, rf7a; if ((ifp->if_flags & IFF_RUNNING) == 0) { if (idx == 0) { memset(&lo_save, 0, sizeof(lo_save)); } else if (init_rf_atten < 0) { lo = bwi_get_rf_lo(mac, rf_atten, 2 * bbp_atten); memcpy(&lo_save, lo, sizeof(lo_save)); } else { lo = bwi_get_rf_lo(mac, init_rf_atten, 0); memcpy(&lo_save, lo, sizeof(lo_save)); } devi_ctrl = 0; adj_rf7a = 0; /* * XXX * Linux driver overflows 'val' */ if (init_rf_atten >= 0) { int val; val = rf_atten * 2 + bbp_atten; if (val > 14) { adj_rf7a = 1; if (val > 17) devi_ctrl = 1; if (val > 19) devi_ctrl = 2; } } } else { lo = bwi_get_rf_lo(mac, rf_atten, 2 * bbp_atten); if (!bwi_rf_lo_isused(mac, lo)) continue; memcpy(&lo_save, lo, sizeof(lo_save)); devi_ctrl = 3; adj_rf7a = 0; } RF_WRITE(mac, BWI_RFR_ATTEN, rf_atten); tp_ctrl2 = mac->mac_tpctl.tp_ctrl2; if (init_rf_atten < 0) tp_ctrl2 |= (3 << 4); RF_WRITE(mac, BWI_RFR_TXPWR, tp_ctrl2); DELAY(10); bwi_phy_set_bbp_atten(mac, bbp_atten * 2); rf7a = orig_rf7a & 0xfff0; if (adj_rf7a) rf7a |= 0x8; RF_WRITE(mac, 0x7a, rf7a); lo = bwi_get_rf_lo(mac, rf_lo_measure_order[idx], bbp_atten * 2); bwi_rf_lo_measure_11g(mac, &lo_save, lo, devi_ctrl); } } return (devi_ctrl); #undef RF_ATTEN_LISTSZ #undef BBP_ATTEN_MAX } static void bwi_rf_lo_measure_11g(struct bwi_mac *mac, const struct bwi_rf_lo *src_lo, struct bwi_rf_lo *dst_lo, uint8_t devi_ctrl) { #define LO_ADJUST_MIN 1 #define LO_ADJUST_MAX 8 #define LO_ADJUST(hi, lo) { .ctrl_hi = hi, .ctrl_lo = lo } static const struct bwi_rf_lo rf_lo_adjust[LO_ADJUST_MAX] = { LO_ADJUST(1, 1), LO_ADJUST(1, 0), LO_ADJUST(1, -1), LO_ADJUST(0, -1), LO_ADJUST(-1, -1), LO_ADJUST(-1, 0), LO_ADJUST(-1, 1), LO_ADJUST(0, 1) }; #undef LO_ADJUST struct bwi_rf_lo lo_min; uint32_t devi_min; int found, loop_count, adjust_state; memcpy(&lo_min, src_lo, sizeof(lo_min)); RF_LO_WRITE(mac, &lo_min); devi_min = bwi_rf_lo_devi_measure(mac, devi_ctrl); loop_count = 12; /* XXX */ adjust_state = 0; do { struct bwi_rf_lo lo_base; int i, fin; found = 0; if (adjust_state == 0) { i = LO_ADJUST_MIN; fin = LO_ADJUST_MAX; } else if (adjust_state % 2 == 0) { i = adjust_state - 1; fin = adjust_state + 1; } else { i = adjust_state - 2; fin = adjust_state + 2; } if (i < LO_ADJUST_MIN) i += LO_ADJUST_MAX; KASSERT(i <= LO_ADJUST_MAX && i >= LO_ADJUST_MIN); if (fin > LO_ADJUST_MAX) fin -= LO_ADJUST_MAX; KASSERT(fin <= LO_ADJUST_MAX && fin >= LO_ADJUST_MIN); memcpy(&lo_base, &lo_min, sizeof(lo_base)); for (;;) { struct bwi_rf_lo lo; lo.ctrl_hi = lo_base.ctrl_hi + rf_lo_adjust[i - 1].ctrl_hi; lo.ctrl_lo = lo_base.ctrl_lo + rf_lo_adjust[i - 1].ctrl_lo; if (abs(lo.ctrl_lo) < 9 && abs(lo.ctrl_hi) < 9) { uint32_t devi; RF_LO_WRITE(mac, &lo); devi = bwi_rf_lo_devi_measure(mac, devi_ctrl); if (devi < devi_min) { devi_min = devi; adjust_state = i; found = 1; memcpy(&lo_min, &lo, sizeof(lo_min)); } } if (i == fin) break; if (i == LO_ADJUST_MAX) i = LO_ADJUST_MIN; else ++i; } } while (loop_count-- && found); memcpy(dst_lo, &lo_min, sizeof(*dst_lo)); #undef LO_ADJUST_MIN #undef LO_ADJUST_MAX } static void bwi_rf_calc_nrssi_slope_11b(struct bwi_mac *mac) { #define SAVE_RF_MAX 3 #define SAVE_PHY_MAX 8 static const uint16_t save_rf_regs[SAVE_RF_MAX] = { 0x7a, 0x52, 0x43 }; static const uint16_t save_phy_regs[SAVE_PHY_MAX] = { 0x30, 0x26, 0x15, 0x2a, 0x20, 0x5a, 0x59, 0x58 }; struct bwi_softc *sc = mac->mac_sc; struct bwi_rf *rf = &mac->mac_rf; struct bwi_phy *phy = &mac->mac_phy; uint16_t save_rf[SAVE_RF_MAX]; uint16_t save_phy[SAVE_PHY_MAX]; uint16_t ant_div, chan_ex; int16_t nrssi[2]; int i; /* * Save RF/PHY registers for later restoration */ for (i = 0; i < SAVE_RF_MAX; ++i) save_rf[i] = RF_READ(mac, save_rf_regs[i]); for (i = 0; i < SAVE_PHY_MAX; ++i) save_phy[i] = PHY_READ(mac, save_phy_regs[i]); ant_div = CSR_READ_2(sc, BWI_RF_ANTDIV); (void)CSR_READ_2(sc, BWI_BBP_ATTEN); chan_ex = CSR_READ_2(sc, BWI_RF_CHAN_EX); /* * Calculate nrssi0 */ if (phy->phy_rev >= 5) RF_CLRBITS(mac, 0x7a, 0xff80); else RF_CLRBITS(mac, 0x7a, 0xfff0); PHY_WRITE(mac, 0x30, 0xff); CSR_WRITE_2(sc, BWI_BPHY_CTRL, 0x7f7f); PHY_WRITE(mac, 0x26, 0); PHY_SETBITS(mac, 0x15, 0x20); PHY_WRITE(mac, 0x2a, 0x8a3); RF_SETBITS(mac, 0x7a, 0x80); nrssi[0] = (int16_t)PHY_READ(mac, 0x27); /* * Calculate nrssi1 */ RF_CLRBITS(mac, 0x7a, 0xff80); if (phy->phy_version >= 2) CSR_WRITE_2(sc, BWI_BBP_ATTEN, 0x40); else if (phy->phy_version == 0) CSR_WRITE_2(sc, BWI_BBP_ATTEN, 0x122); else CSR_CLRBITS_2(sc, BWI_RF_CHAN_EX, 0xdfff); PHY_WRITE(mac, 0x20, 0x3f3f); PHY_WRITE(mac, 0x15, 0xf330); RF_WRITE(mac, 0x5a, 0x60); RF_CLRBITS(mac, 0x43, 0xff0f); PHY_WRITE(mac, 0x5a, 0x480); PHY_WRITE(mac, 0x59, 0x810); PHY_WRITE(mac, 0x58, 0xd); DELAY(20); nrssi[1] = (int16_t)PHY_READ(mac, 0x27); /* * Restore saved RF/PHY registers */ PHY_WRITE(mac, save_phy_regs[0], save_phy[0]); RF_WRITE(mac, save_rf_regs[0], save_rf[0]); CSR_WRITE_2(sc, BWI_RF_ANTDIV, ant_div); for (i = 1; i < 4; ++i) PHY_WRITE(mac, save_phy_regs[i], save_phy[i]); bwi_rf_workaround(mac, rf->rf_curchan); if (phy->phy_version != 0) CSR_WRITE_2(sc, BWI_RF_CHAN_EX, chan_ex); for (; i < SAVE_PHY_MAX; ++i) PHY_WRITE(mac, save_phy_regs[i], save_phy[i]); for (i = 1; i < SAVE_RF_MAX; ++i) RF_WRITE(mac, save_rf_regs[i], save_rf[i]); /* * Install calculated narrow RSSI values */ if (nrssi[0] == nrssi[1]) rf->rf_nrssi_slope = 0x10000; else rf->rf_nrssi_slope = 0x400000 / (nrssi[0] - nrssi[1]); if (nrssi[0] <= -4) { rf->rf_nrssi[0] = nrssi[0]; rf->rf_nrssi[1] = nrssi[1]; } #undef SAVE_RF_MAX #undef SAVE_PHY_MAX } static void bwi_rf_set_nrssi_ofs_11g(struct bwi_mac *mac) { #define SAVE_RF_MAX 2 #define SAVE_PHY_COMM_MAX 10 #define SAVE_PHY6_MAX 8 static const uint16_t save_rf_regs[SAVE_RF_MAX] = { 0x7a, 0x43 }; static const uint16_t save_phy_comm_regs[SAVE_PHY_COMM_MAX] = { 0x0001, 0x0811, 0x0812, 0x0814, 0x0815, 0x005a, 0x0059, 0x0058, 0x000a, 0x0003 }; static const uint16_t save_phy6_regs[SAVE_PHY6_MAX] = { 0x002e, 0x002f, 0x080f, 0x0810, 0x0801, 0x0060, 0x0014, 0x0478 }; struct bwi_phy *phy = &mac->mac_phy; uint16_t save_rf[SAVE_RF_MAX]; uint16_t save_phy_comm[SAVE_PHY_COMM_MAX]; uint16_t save_phy6[SAVE_PHY6_MAX]; uint16_t rf7b = 0xffff; int16_t nrssi; int i, phy6_idx = 0; for (i = 0; i < SAVE_PHY_COMM_MAX; ++i) save_phy_comm[i] = PHY_READ(mac, save_phy_comm_regs[i]); for (i = 0; i < SAVE_RF_MAX; ++i) save_rf[i] = RF_READ(mac, save_rf_regs[i]); PHY_CLRBITS(mac, 0x429, 0x8000); PHY_FILT_SETBITS(mac, 0x1, 0x3fff, 0x4000); PHY_SETBITS(mac, 0x811, 0xc); PHY_FILT_SETBITS(mac, 0x812, 0xfff3, 0x4); PHY_CLRBITS(mac, 0x802, 0x3); if (phy->phy_rev >= 6) { for (i = 0; i < SAVE_PHY6_MAX; ++i) save_phy6[i] = PHY_READ(mac, save_phy6_regs[i]); PHY_WRITE(mac, 0x2e, 0); PHY_WRITE(mac, 0x2f, 0); PHY_WRITE(mac, 0x80f, 0); PHY_WRITE(mac, 0x810, 0); PHY_SETBITS(mac, 0x478, 0x100); PHY_SETBITS(mac, 0x801, 0x40); PHY_SETBITS(mac, 0x60, 0x40); PHY_SETBITS(mac, 0x14, 0x200); } RF_SETBITS(mac, 0x7a, 0x70); RF_SETBITS(mac, 0x7a, 0x80); DELAY(30); nrssi = bwi_nrssi_11g(mac); if (nrssi == 31) { for (i = 7; i >= 4; --i) { RF_WRITE(mac, 0x7b, i); DELAY(20); nrssi = bwi_nrssi_11g(mac); if (nrssi < 31 && rf7b == 0xffff) rf7b = i; } if (rf7b == 0xffff) rf7b = 4; } else { struct bwi_gains gains; RF_CLRBITS(mac, 0x7a, 0xff80); PHY_SETBITS(mac, 0x814, 0x1); PHY_CLRBITS(mac, 0x815, 0x1); PHY_SETBITS(mac, 0x811, 0xc); PHY_SETBITS(mac, 0x812, 0xc); PHY_SETBITS(mac, 0x811, 0x30); PHY_SETBITS(mac, 0x812, 0x30); PHY_WRITE(mac, 0x5a, 0x480); PHY_WRITE(mac, 0x59, 0x810); PHY_WRITE(mac, 0x58, 0xd); if (phy->phy_version == 0) PHY_WRITE(mac, 0x3, 0x122); else PHY_SETBITS(mac, 0xa, 0x2000); PHY_SETBITS(mac, 0x814, 0x4); PHY_CLRBITS(mac, 0x815, 0x4); PHY_FILT_SETBITS(mac, 0x3, 0xff9f, 0x40); RF_SETBITS(mac, 0x7a, 0xf); memset(&gains, 0, sizeof(gains)); gains.tbl_gain1 = 3; gains.tbl_gain2 = 0; gains.phy_gain = 1; bwi_set_gains(mac, &gains); RF_FILT_SETBITS(mac, 0x43, 0xf0, 0xf); DELAY(30); nrssi = bwi_nrssi_11g(mac); if (nrssi == -32) { for (i = 0; i < 4; ++i) { RF_WRITE(mac, 0x7b, i); DELAY(20); nrssi = bwi_nrssi_11g(mac); if (nrssi > -31 && rf7b == 0xffff) rf7b = i; } if (rf7b == 0xffff) rf7b = 3; } else { rf7b = 0; } } RF_WRITE(mac, 0x7b, rf7b); /* * Restore saved RF/PHY registers */ if (phy->phy_rev >= 6) { for (phy6_idx = 0; phy6_idx < 4; ++phy6_idx) { PHY_WRITE(mac, save_phy6_regs[phy6_idx], save_phy6[phy6_idx]); } } /* Saved PHY registers 0, 1, 2 are handled later */ for (i = 3; i < SAVE_PHY_COMM_MAX; ++i) PHY_WRITE(mac, save_phy_comm_regs[i], save_phy_comm[i]); for (i = SAVE_RF_MAX - 1; i >= 0; --i) RF_WRITE(mac, save_rf_regs[i], save_rf[i]); PHY_SETBITS(mac, 0x802, 0x3); PHY_SETBITS(mac, 0x429, 0x8000); bwi_set_gains(mac, NULL); if (phy->phy_rev >= 6) { for (; phy6_idx < SAVE_PHY6_MAX; ++phy6_idx) { PHY_WRITE(mac, save_phy6_regs[phy6_idx], save_phy6[phy6_idx]); } } PHY_WRITE(mac, save_phy_comm_regs[0], save_phy_comm[0]); PHY_WRITE(mac, save_phy_comm_regs[2], save_phy_comm[2]); PHY_WRITE(mac, save_phy_comm_regs[1], save_phy_comm[1]); #undef SAVE_RF_MAX #undef SAVE_PHY_COMM_MAX #undef SAVE_PHY6_MAX } static void bwi_rf_calc_nrssi_slope_11g(struct bwi_mac *mac) { #define SAVE_RF_MAX 3 #define SAVE_PHY_COMM_MAX 4 #define SAVE_PHY3_MAX 8 static const uint16_t save_rf_regs[SAVE_RF_MAX] = { 0x7a, 0x52, 0x43 }; static const uint16_t save_phy_comm_regs[SAVE_PHY_COMM_MAX] = { 0x15, 0x5a, 0x59, 0x58 }; static const uint16_t save_phy3_regs[SAVE_PHY3_MAX] = { 0x002e, 0x002f, 0x080f, 0x0810, 0x0801, 0x0060, 0x0014, 0x0478 }; struct bwi_softc *sc = mac->mac_sc; struct bwi_phy *phy = &mac->mac_phy; struct bwi_rf *rf = &mac->mac_rf; uint16_t save_rf[SAVE_RF_MAX]; uint16_t save_phy_comm[SAVE_PHY_COMM_MAX]; uint16_t save_phy3[SAVE_PHY3_MAX]; uint16_t ant_div, bbp_atten, chan_ex; struct bwi_gains gains; int16_t nrssi[2]; int i, phy3_idx = 0; if (rf->rf_rev >= 9) return; else if (rf->rf_rev == 8) bwi_rf_set_nrssi_ofs_11g(mac); PHY_CLRBITS(mac, 0x429, 0x8000); PHY_CLRBITS(mac, 0x802, 0x3); /* * Save RF/PHY registers for later restoration */ ant_div = CSR_READ_2(sc, BWI_RF_ANTDIV); CSR_SETBITS_2(sc, BWI_RF_ANTDIV, 0x8000); for (i = 0; i < SAVE_RF_MAX; ++i) save_rf[i] = RF_READ(mac, save_rf_regs[i]); for (i = 0; i < SAVE_PHY_COMM_MAX; ++i) save_phy_comm[i] = PHY_READ(mac, save_phy_comm_regs[i]); bbp_atten = CSR_READ_2(sc, BWI_BBP_ATTEN); chan_ex = CSR_READ_2(sc, BWI_RF_CHAN_EX); if (phy->phy_rev >= 3) { for (i = 0; i < SAVE_PHY3_MAX; ++i) save_phy3[i] = PHY_READ(mac, save_phy3_regs[i]); PHY_WRITE(mac, 0x2e, 0); PHY_WRITE(mac, 0x810, 0); if (phy->phy_rev == 4 || phy->phy_rev == 6 || phy->phy_rev == 7) { PHY_SETBITS(mac, 0x478, 0x100); PHY_SETBITS(mac, 0x810, 0x40); } else if (phy->phy_rev == 3 || phy->phy_rev == 5) PHY_CLRBITS(mac, 0x810, 0x40); PHY_SETBITS(mac, 0x60, 0x40); PHY_SETBITS(mac, 0x14, 0x200); } /* * Calculate nrssi0 */ RF_SETBITS(mac, 0x7a, 0x70); memset(&gains, 0, sizeof(gains)); gains.tbl_gain1 = 0; gains.tbl_gain2 = 8; gains.phy_gain = 0; bwi_set_gains(mac, &gains); RF_CLRBITS(mac, 0x7a, 0xff08); if (phy->phy_rev >= 2) { PHY_FILT_SETBITS(mac, 0x811, 0xffcf, 0x30); PHY_FILT_SETBITS(mac, 0x812, 0xffcf, 0x10); } RF_SETBITS(mac, 0x7a, 0x80); DELAY(20); nrssi[0] = bwi_nrssi_11g(mac); /* * Calculate nrssi1 */ RF_CLRBITS(mac, 0x7a, 0xff80); if (phy->phy_version >= 2) PHY_FILT_SETBITS(mac, 0x3, 0xff9f, 0x40); CSR_SETBITS_2(sc, BWI_RF_CHAN_EX, 0x2000); RF_SETBITS(mac, 0x7a, 0xf); PHY_WRITE(mac, 0x15, 0xf330); if (phy->phy_rev >= 2) { PHY_FILT_SETBITS(mac, 0x812, 0xffcf, 0x20); PHY_FILT_SETBITS(mac, 0x811, 0xffcf, 0x20); } memset(&gains, 0, sizeof(gains)); gains.tbl_gain1 = 3; gains.tbl_gain2 = 0; gains.phy_gain = 1; bwi_set_gains(mac, &gains); if (rf->rf_rev == 8) { RF_WRITE(mac, 0x43, 0x1f); } else { RF_FILT_SETBITS(mac, 0x52, 0xff0f, 0x60); RF_FILT_SETBITS(mac, 0x43, 0xfff0, 0x9); } PHY_WRITE(mac, 0x5a, 0x480); PHY_WRITE(mac, 0x59, 0x810); PHY_WRITE(mac, 0x58, 0xd); DELAY(20); nrssi[1] = bwi_nrssi_11g(mac); /* * Install calculated narrow RSSI values */ if (nrssi[1] == nrssi[0]) rf->rf_nrssi_slope = 0x10000; else rf->rf_nrssi_slope = 0x400000 / (nrssi[0] - nrssi[1]); if (nrssi[0] >= -4) { rf->rf_nrssi[0] = nrssi[1]; rf->rf_nrssi[1] = nrssi[0]; } /* * Restore saved RF/PHY registers */ if (phy->phy_rev >= 3) { for (phy3_idx = 0; phy3_idx < 4; ++phy3_idx) { PHY_WRITE(mac, save_phy3_regs[phy3_idx], save_phy3[phy3_idx]); } } if (phy->phy_rev >= 2) { PHY_CLRBITS(mac, 0x812, 0x30); PHY_CLRBITS(mac, 0x811, 0x30); } for (i = 0; i < SAVE_RF_MAX; ++i) RF_WRITE(mac, save_rf_regs[i], save_rf[i]); CSR_WRITE_2(sc, BWI_RF_ANTDIV, ant_div); CSR_WRITE_2(sc, BWI_BBP_ATTEN, bbp_atten); CSR_WRITE_2(sc, BWI_RF_CHAN_EX, chan_ex); for (i = 0; i < SAVE_PHY_COMM_MAX; ++i) PHY_WRITE(mac, save_phy_comm_regs[i], save_phy_comm[i]); bwi_rf_workaround(mac, rf->rf_curchan); PHY_SETBITS(mac, 0x802, 0x3); bwi_set_gains(mac, NULL); PHY_SETBITS(mac, 0x429, 0x8000); if (phy->phy_rev >= 3) { for (; phy3_idx < SAVE_PHY3_MAX; ++phy3_idx) { PHY_WRITE(mac, save_phy3_regs[phy3_idx], save_phy3[phy3_idx]); } } bwi_rf_init_sw_nrssi_table(mac); bwi_rf_set_nrssi_thr_11g(mac); #undef SAVE_RF_MAX #undef SAVE_PHY_COMM_MAX #undef SAVE_PHY3_MAX } static void bwi_rf_init_sw_nrssi_table(struct bwi_mac *mac) { struct bwi_rf *rf = &mac->mac_rf; int d, i; d = 0x1f - rf->rf_nrssi[0]; for (i = 0; i < BWI_NRSSI_TBLSZ; ++i) { int val; val = (((i - d) * rf->rf_nrssi_slope) / 0x10000) + 0x3a; if (val < 0) val = 0; else if (val > 0x3f) val = 0x3f; rf->rf_nrssi_table[i] = val; } } static void bwi_rf_init_hw_nrssi_table(struct bwi_mac *mac, uint16_t adjust) { int i; for (i = 0; i < BWI_NRSSI_TBLSZ; ++i) { int16_t val; val = bwi_nrssi_read(mac, i); val -= adjust; if (val < -32) val = -32; else if (val > 31) val = 31; bwi_nrssi_write(mac, i, val); } } static void bwi_rf_set_nrssi_thr_11b(struct bwi_mac *mac) { struct bwi_rf *rf = &mac->mac_rf; int32_t thr; if (rf->rf_type != BWI_RF_T_BCM2050 || (mac->mac_sc->sc_card_flags & BWI_CARD_F_SW_NRSSI) == 0) return; /* * Calculate nrssi threshold */ if (rf->rf_rev >= 6) { thr = (rf->rf_nrssi[1] - rf->rf_nrssi[0]) * 32; thr += 20 * (rf->rf_nrssi[0] + 1); thr /= 40; } else { thr = rf->rf_nrssi[1] - 5; } if (thr < 0) thr = 0; else if (thr > 0x3e) thr = 0x3e; PHY_READ(mac, BWI_PHYR_NRSSI_THR_11B); /* dummy read */ PHY_WRITE(mac, BWI_PHYR_NRSSI_THR_11B, (((uint16_t)thr) << 8) | 0x1c); if (rf->rf_rev >= 6) { PHY_WRITE(mac, 0x87, 0xe0d); PHY_WRITE(mac, 0x86, 0xc0b); PHY_WRITE(mac, 0x85, 0xa09); PHY_WRITE(mac, 0x84, 0x808); PHY_WRITE(mac, 0x83, 0x808); PHY_WRITE(mac, 0x82, 0x604); PHY_WRITE(mac, 0x81, 0x302); PHY_WRITE(mac, 0x80, 0x100); } } static int32_t _nrssi_threshold(const struct bwi_rf *rf, int32_t val) { val *= (rf->rf_nrssi[1] - rf->rf_nrssi[0]); val += (rf->rf_nrssi[0] << 6); if (val < 32) val += 31; else val += 32; val >>= 6; if (val < -31) val = -31; else if (val > 31) val = 31; return (val); } static void bwi_rf_set_nrssi_thr_11g(struct bwi_mac *mac) { int32_t thr1, thr2; uint16_t thr; /* * Find the two nrssi thresholds */ if ((mac->mac_phy.phy_flags & BWI_PHY_F_LINKED) == 0 || (mac->mac_sc->sc_card_flags & BWI_CARD_F_SW_NRSSI) == 0) { int16_t nrssi; nrssi = bwi_nrssi_read(mac, 0x20); if (nrssi >= 32) nrssi -= 64; if (nrssi < 3) { thr1 = 0x2b; thr2 = 0x27; } else { thr1 = 0x2d; thr2 = 0x2b; } } else { /* TODO Interfere mode */ thr1 = _nrssi_threshold(&mac->mac_rf, 0x11); thr2 = _nrssi_threshold(&mac->mac_rf, 0xe); } #define NRSSI_THR1_MASK 0x003f #define NRSSI_THR2_MASK 0x0fc0 thr = __SHIFTIN((uint32_t)thr1, NRSSI_THR1_MASK) | __SHIFTIN((uint32_t)thr2, NRSSI_THR2_MASK); PHY_FILT_SETBITS(mac, BWI_PHYR_NRSSI_THR_11G, 0xf000, thr); #undef NRSSI_THR1_MASK #undef NRSSI_THR2_MASK } static void bwi_rf_clear_tssi(struct bwi_mac *mac) { /* XXX use function pointer */ if (mac->mac_phy.phy_mode == IEEE80211_MODE_11A) { /* TODO: 11A */ } else { uint16_t val; int i; val = __SHIFTIN(BWI_INVALID_TSSI, BWI_LO_TSSI_MASK) | __SHIFTIN(BWI_INVALID_TSSI, BWI_HI_TSSI_MASK); for (i = 0; i < 2; ++i) { MOBJ_WRITE_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_TSSI_DS + (i * 2), val); } for (i = 0; i < 2; ++i) { MOBJ_WRITE_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_TSSI_OFDM + (i * 2), val); } } } static void bwi_rf_clear_state(struct bwi_rf *rf) { int i; rf->rf_flags &= ~BWI_RF_CLEAR_FLAGS; memset(rf->rf_lo, 0, sizeof(rf->rf_lo)); memset(rf->rf_lo_used, 0, sizeof(rf->rf_lo_used)); rf->rf_nrssi_slope = 0; rf->rf_nrssi[0] = BWI_INVALID_NRSSI; rf->rf_nrssi[1] = BWI_INVALID_NRSSI; for (i = 0; i < BWI_NRSSI_TBLSZ; ++i) rf->rf_nrssi_table[i] = i; rf->rf_lo_gain = 0; rf->rf_rx_gain = 0; memcpy(rf->rf_txpower_map, rf->rf_txpower_map0, sizeof(rf->rf_txpower_map)); rf->rf_idle_tssi = rf->rf_idle_tssi0; } static void bwi_rf_on_11a(struct bwi_mac *mac) { /* TODO: 11A */ } static void bwi_rf_on_11bg(struct bwi_mac *mac) { struct bwi_phy *phy = &mac->mac_phy; PHY_WRITE(mac, 0x15, 0x8000); PHY_WRITE(mac, 0x15, 0xcc00); if (phy->phy_flags & BWI_PHY_F_LINKED) PHY_WRITE(mac, 0x15, 0xc0); else PHY_WRITE(mac, 0x15, 0); bwi_rf_set_chan(mac, 6 /* XXX */, 1); } static void bwi_rf_set_ant_mode(struct bwi_mac *mac, int ant_mode) { struct bwi_softc *sc = mac->mac_sc; struct bwi_phy *phy = &mac->mac_phy; uint16_t val; KASSERT(ant_mode == BWI_ANT_MODE_0 || ant_mode == BWI_ANT_MODE_1 || ant_mode == BWI_ANT_MODE_AUTO); HFLAGS_CLRBITS(mac, BWI_HFLAG_AUTO_ANTDIV); if (phy->phy_mode == IEEE80211_MODE_11B) { /* NOTE: v4/v3 conflicts, take v3 */ if (mac->mac_rev == 2) val = BWI_ANT_MODE_AUTO; else val = ant_mode; val <<= 7; PHY_FILT_SETBITS(mac, 0x3e2, 0xfe7f, val); } else { /* 11a/g */ /* XXX reg/value naming */ val = ant_mode << 7; PHY_FILT_SETBITS(mac, 0x401, 0x7e7f, val); if (ant_mode == BWI_ANT_MODE_AUTO) PHY_CLRBITS(mac, 0x42b, 0x100); if (phy->phy_mode == IEEE80211_MODE_11A) { /* TODO: 11A */ } else { /* 11g */ if (ant_mode == BWI_ANT_MODE_AUTO) PHY_SETBITS(mac, 0x48c, 0x2000); else PHY_CLRBITS(mac, 0x48c, 0x2000); if (phy->phy_rev >= 2) { PHY_SETBITS(mac, 0x461, 0x10); PHY_FILT_SETBITS(mac, 0x4ad, 0xff00, 0x15); if (phy->phy_rev == 2) { PHY_WRITE(mac, 0x427, 0x8); } else { PHY_FILT_SETBITS(mac, 0x427, 0xff00, 0x8); } if (phy->phy_rev >= 6) PHY_WRITE(mac, 0x49b, 0xdc); } } } /* XXX v4 set AUTO_ANTDIV unconditionally */ if (ant_mode == BWI_ANT_MODE_AUTO) HFLAGS_SETBITS(mac, BWI_HFLAG_AUTO_ANTDIV); val = ant_mode << 8; MOBJ_FILT_SETBITS_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_TX_BEACON, 0xfc3f, val); MOBJ_FILT_SETBITS_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_TX_ACK, 0xfc3f, val); MOBJ_FILT_SETBITS_2(mac, BWI_COMM_MOBJ, BWI_COMM_MOBJ_TX_PROBE_RESP, 0xfc3f, val); /* XXX what's these */ if (phy->phy_mode == IEEE80211_MODE_11B) CSR_SETBITS_2(sc, 0x5e, 0x4); CSR_WRITE_4(sc, 0x100, 0x1000000); if (mac->mac_rev < 5) CSR_WRITE_4(sc, 0x10c, 0x1000000); mac->mac_rf.rf_ant_mode = ant_mode; } static int bwi_rf_get_latest_tssi(struct bwi_mac *mac, int8_t tssi[], uint16_t ofs) { int i; for (i = 0; i < 4; ) { uint16_t val; val = MOBJ_READ_2(mac, BWI_COMM_MOBJ, ofs + i); tssi[i++] = (int8_t)__SHIFTOUT(val, BWI_LO_TSSI_MASK); tssi[i++] = (int8_t)__SHIFTOUT(val, BWI_HI_TSSI_MASK); } for (i = 0; i < 4; ++i) { if (tssi[i] == BWI_INVALID_TSSI) return (EINVAL); } return (0); } static int bwi_rf_tssi2dbm(struct bwi_mac *mac, int8_t tssi, int8_t *txpwr) { struct bwi_rf *rf = &mac->mac_rf; int pwr_idx; pwr_idx = rf->rf_idle_tssi + (int)tssi - rf->rf_base_tssi; #if 0 if (pwr_idx < 0 || pwr_idx >= BWI_TSSI_MAX) return (EINVAL); #else if (pwr_idx < 0) pwr_idx = 0; else if (pwr_idx >= BWI_TSSI_MAX) pwr_idx = BWI_TSSI_MAX - 1; #endif *txpwr = rf->rf_txpower_map[pwr_idx]; return (0); } static int bwi_rf_calc_rssi_bcm2050(struct bwi_mac *mac, const struct bwi_rxbuf_hdr *hdr) { uint16_t flags1, flags3; int rssi, lna_gain; rssi = hdr->rxh_rssi; flags1 = le16toh(hdr->rxh_flags1); flags3 = le16toh(hdr->rxh_flags3); #define NEW_BCM2050_RSSI #ifdef NEW_BCM2050_RSSI if (flags1 & BWI_RXH_F1_OFDM) { if (rssi > 127) rssi -= 256; if (flags3 & BWI_RXH_F3_BCM2050_RSSI) rssi += 17; else rssi -= 4; return (rssi); } if (mac->mac_sc->sc_card_flags & BWI_CARD_F_SW_NRSSI) { struct bwi_rf *rf = &mac->mac_rf; if (rssi >= BWI_NRSSI_TBLSZ) rssi = BWI_NRSSI_TBLSZ - 1; rssi = ((31 - (int)rf->rf_nrssi_table[rssi]) * -131) / 128; rssi -= 67; } else { rssi = ((31 - rssi) * -149) / 128; rssi -= 68; } if (mac->mac_phy.phy_mode != IEEE80211_MODE_11G) return (rssi); if (flags3 & BWI_RXH_F3_BCM2050_RSSI) rssi += 20; lna_gain = __SHIFTOUT(le16toh(hdr->rxh_phyinfo), BWI_RXH_PHYINFO_LNAGAIN); /* [TRC: XXX This causes some seriously verbose output. I hope it just verbose and not actually a symptom of a problem.] DPRINTF(mac->mac_sc, BWI_DBG_RF | BWI_DBG_RX, "lna_gain %d, phyinfo 0x%04x\n", lna_gain, le16toh(hdr->rxh_phyinfo)); */ switch (lna_gain) { case 0: rssi += 27; break; case 1: rssi += 6; break; case 2: rssi += 12; break; case 3: /* * XXX * According to v3 spec, we should do _nothing_ here, * but it seems that the result RSSI will be too low * (relative to what ath(4) says). Raise it a little * bit. */ rssi += 5; break; default: panic("impossible lna gain %d", lna_gain); } #else /* !NEW_BCM2050_RSSI */ lna_gain = 0; /* shut up gcc warning */ if (flags1 & BWI_RXH_F1_OFDM) { if (rssi > 127) rssi -= 256; rssi = (rssi * 73) / 64; if (flags3 & BWI_RXH_F3_BCM2050_RSSI) rssi += 25; else rssi -= 3; return (rssi); } if (mac->mac_sc->sc_card_flags & BWI_CARD_F_SW_NRSSI) { struct bwi_rf *rf = &mac->mac_rf; if (rssi >= BWI_NRSSI_TBLSZ) rssi = BWI_NRSSI_TBLSZ - 1; rssi = ((31 - (int)rf->rf_nrssi_table[rssi]) * -131) / 128; rssi -= 57; } else { rssi = ((31 - rssi) * -149) / 128; rssi -= 68; } if (mac->mac_phy.phy_mode != IEEE80211_MODE_11G) return (rssi); if (flags3 & BWI_RXH_F3_BCM2050_RSSI) rssi += 25; #endif /* NEW_BCM2050_RSSI */ return (rssi); } static int bwi_rf_calc_rssi_bcm2053(struct bwi_mac *mac, const struct bwi_rxbuf_hdr *hdr) { uint16_t flags1; int rssi; rssi = (((int)hdr->rxh_rssi - 11) * 103) / 64; flags1 = le16toh(hdr->rxh_flags1); if (flags1 & BWI_RXH_F1_BCM2053_RSSI) rssi -= 109; else rssi -= 83; return (rssi); } static int bwi_rf_calc_rssi_bcm2060(struct bwi_mac *mac, const struct bwi_rxbuf_hdr *hdr) { int rssi; rssi = hdr->rxh_rssi; if (rssi > 127) rssi -= 256; return (rssi); } static uint16_t bwi_rf_lo_measure_11b(struct bwi_mac *mac) { uint16_t val; int i; val = 0; for (i = 0; i < 10; ++i) { PHY_WRITE(mac, 0x15, 0xafa0); DELAY(1); PHY_WRITE(mac, 0x15, 0xefa0); DELAY(10); PHY_WRITE(mac, 0x15, 0xffa0); DELAY(40); val += PHY_READ(mac, 0x2c); } return (val); } static void bwi_rf_lo_update_11b(struct bwi_mac *mac) { struct bwi_softc *sc = mac->mac_sc; struct bwi_rf *rf = &mac->mac_rf; struct rf_saveregs regs; uint16_t rf_val, phy_val, min_val, val; uint16_t rf52, bphy_ctrl; int i; DPRINTF(sc, BWI_DBG_RF | BWI_DBG_INIT, "%s enter\n", __func__); memset(®s, 0, sizeof(regs)); bphy_ctrl = 0; /* * Save RF/PHY registers for later restoration */ SAVE_PHY_REG(mac, ®s, 15); rf52 = RF_READ(mac, 0x52) & 0xfff0; if (rf->rf_type == BWI_RF_T_BCM2050) { SAVE_PHY_REG(mac, ®s, 0a); SAVE_PHY_REG(mac, ®s, 2a); SAVE_PHY_REG(mac, ®s, 35); SAVE_PHY_REG(mac, ®s, 03); SAVE_PHY_REG(mac, ®s, 01); SAVE_PHY_REG(mac, ®s, 30); SAVE_RF_REG(mac, ®s, 43); SAVE_RF_REG(mac, ®s, 7a); bphy_ctrl = CSR_READ_2(sc, BWI_BPHY_CTRL); SAVE_RF_REG(mac, ®s, 52); regs.rf_52 &= 0xf0; PHY_WRITE(mac, 0x30, 0xff); CSR_WRITE_2(sc, BWI_PHY_CTRL, 0x3f3f); PHY_WRITE(mac, 0x35, regs.phy_35 & 0xff7f); RF_WRITE(mac, 0x7a, regs.rf_7a & 0xfff0); } PHY_WRITE(mac, 0x15, 0xb000); if (rf->rf_type == BWI_RF_T_BCM2050) { PHY_WRITE(mac, 0x2b, 0x203); PHY_WRITE(mac, 0x2a, 0x8a3); } else { PHY_WRITE(mac, 0x2b, 0x1402); } /* * Setup RF signal */ rf_val = 0; min_val = UINT16_MAX; for (i = 0; i < 4; ++i) { RF_WRITE(mac, 0x52, rf52 | i); bwi_rf_lo_measure_11b(mac); /* Ignore return value */ } for (i = 0; i < 10; ++i) { RF_WRITE(mac, 0x52, rf52 | i); val = bwi_rf_lo_measure_11b(mac) / 10; if (val < min_val) { min_val = val; rf_val = i; } } RF_WRITE(mac, 0x52, rf52 | rf_val); /* * Setup PHY signal */ phy_val = 0; min_val = UINT16_MAX; for (i = -4; i < 5; i += 2) { int j; for (j = -4; j < 5; j += 2) { uint16_t phy2f; phy2f = (0x100 * i) + j; if (j < 0) phy2f += 0x100; PHY_WRITE(mac, 0x2f, phy2f); val = bwi_rf_lo_measure_11b(mac) / 10; if (val < min_val) { min_val = val; phy_val = phy2f; } } } PHY_WRITE(mac, 0x2f, phy_val + 0x101); /* * Restore saved RF/PHY registers */ if (rf->rf_type == BWI_RF_T_BCM2050) { RESTORE_PHY_REG(mac, ®s, 0a); RESTORE_PHY_REG(mac, ®s, 2a); RESTORE_PHY_REG(mac, ®s, 35); RESTORE_PHY_REG(mac, ®s, 03); RESTORE_PHY_REG(mac, ®s, 01); RESTORE_PHY_REG(mac, ®s, 30); RESTORE_RF_REG(mac, ®s, 43); RESTORE_RF_REG(mac, ®s, 7a); RF_FILT_SETBITS(mac, 0x52, 0xf, regs.rf_52); CSR_WRITE_2(sc, BWI_BPHY_CTRL, bphy_ctrl); } RESTORE_PHY_REG(mac, ®s, 15); bwi_rf_workaround(mac, rf->rf_curchan); } /* INTERFACE */ static uint16_t bwi_read_sprom(struct bwi_softc *sc, uint16_t ofs) { return (CSR_READ_2(sc, ofs + BWI_SPROM_START)); } static void bwi_setup_desc32(struct bwi_softc *sc, struct bwi_desc32 *desc_array, int ndesc, int desc_idx, bus_addr_t paddr, int buf_len, int tx) { struct bwi_desc32 *desc = &desc_array[desc_idx]; uint32_t ctrl, addr, addr_hi, addr_lo; addr_lo = __SHIFTOUT(paddr, BWI_DESC32_A_ADDR_MASK); addr_hi = __SHIFTOUT(paddr, BWI_DESC32_A_FUNC_MASK); addr = __SHIFTIN(addr_lo, BWI_DESC32_A_ADDR_MASK) | __SHIFTIN(BWI_DESC32_A_FUNC_TXRX, BWI_DESC32_A_FUNC_MASK); ctrl = __SHIFTIN(buf_len, BWI_DESC32_C_BUFLEN_MASK) | __SHIFTIN(addr_hi, BWI_DESC32_C_ADDRHI_MASK); if (desc_idx == ndesc - 1) ctrl |= BWI_DESC32_C_EOR; if (tx) { /* XXX */ ctrl |= BWI_DESC32_C_FRAME_START | BWI_DESC32_C_FRAME_END | BWI_DESC32_C_INTR; } desc->addr = htole32(addr); desc->ctrl = htole32(ctrl); } static void bwi_power_on(struct bwi_softc *sc, int with_pll) { uint32_t gpio_in, gpio_out, gpio_en, status; DPRINTF(sc, BWI_DBG_MISC, "%s\n", __func__); gpio_in = (sc->sc_conf_read)(sc, BWI_PCIR_GPIO_IN); if (gpio_in & BWI_PCIM_GPIO_PWR_ON) goto back; gpio_out = (sc->sc_conf_read)(sc, BWI_PCIR_GPIO_OUT); gpio_en = (sc->sc_conf_read)(sc, BWI_PCIR_GPIO_ENABLE); gpio_out |= BWI_PCIM_GPIO_PWR_ON; gpio_en |= BWI_PCIM_GPIO_PWR_ON; if (with_pll) { /* Turn off PLL first */ gpio_out |= BWI_PCIM_GPIO_PLL_PWR_OFF; gpio_en |= BWI_PCIM_GPIO_PLL_PWR_OFF; } (sc->sc_conf_write)(sc, BWI_PCIR_GPIO_OUT, gpio_out); (sc->sc_conf_write)(sc, BWI_PCIR_GPIO_ENABLE, gpio_en); DELAY(1000); if (with_pll) { /* Turn on PLL */ gpio_out &= ~BWI_PCIM_GPIO_PLL_PWR_OFF; (sc->sc_conf_write)(sc, BWI_PCIR_GPIO_OUT, gpio_out); DELAY(5000); } back: /* [TRC: XXX This looks totally wrong -- what's PCI doing in here?] */ /* Clear "Signaled Target Abort" */ status = (sc->sc_conf_read)(sc, PCI_COMMAND_STATUS_REG); status &= ~PCI_STATUS_TARGET_TARGET_ABORT; (sc->sc_conf_write)(sc, PCI_COMMAND_STATUS_REG, status); } static int bwi_power_off(struct bwi_softc *sc, int with_pll) { uint32_t gpio_out, gpio_en; DPRINTF(sc, BWI_DBG_MISC, "%s\n", __func__); (sc->sc_conf_read)(sc, BWI_PCIR_GPIO_IN); /* dummy read */ gpio_out = (sc->sc_conf_read)(sc, BWI_PCIR_GPIO_OUT); gpio_en = (sc->sc_conf_read)(sc, BWI_PCIR_GPIO_ENABLE); gpio_out &= ~BWI_PCIM_GPIO_PWR_ON; gpio_en |= BWI_PCIM_GPIO_PWR_ON; if (with_pll) { gpio_out |= BWI_PCIM_GPIO_PLL_PWR_OFF; gpio_en |= BWI_PCIM_GPIO_PLL_PWR_OFF; } (sc->sc_conf_write)(sc, BWI_PCIR_GPIO_OUT, gpio_out); (sc->sc_conf_write)(sc, BWI_PCIR_GPIO_ENABLE, gpio_en); return (0); } static int bwi_regwin_switch(struct bwi_softc *sc, struct bwi_regwin *rw, struct bwi_regwin **old_rw) { int error; if (old_rw != NULL) *old_rw = NULL; if (!BWI_REGWIN_EXIST(rw)) return (EINVAL); if (sc->sc_cur_regwin != rw) { error = bwi_regwin_select(sc, rw->rw_id); if (error) { aprint_error_dev(sc->sc_dev, "can't select regwin %d\n", rw->rw_id); return (error); } } if (old_rw != NULL) *old_rw = sc->sc_cur_regwin; sc->sc_cur_regwin = rw; return (0); } static int bwi_regwin_select(struct bwi_softc *sc, int id) { uint32_t win = BWI_PCIM_REGWIN(id); int i; #define RETRY_MAX 50 for (i = 0; i < RETRY_MAX; ++i) { (sc->sc_conf_write)(sc, BWI_PCIR_SEL_REGWIN, win); if ((sc->sc_conf_read)(sc, BWI_PCIR_SEL_REGWIN) == win) return (0); DELAY(10); } #undef RETRY_MAX return (ENXIO); } static void bwi_regwin_info(struct bwi_softc *sc, uint16_t *type, uint8_t *rev) { uint32_t val; val = CSR_READ_4(sc, BWI_ID_HI); *type = BWI_ID_HI_REGWIN_TYPE(val); *rev = BWI_ID_HI_REGWIN_REV(val); DPRINTF(sc, BWI_DBG_ATTACH, "regwin: type 0x%03x, rev %d," " vendor 0x%04x\n", *type, *rev, __SHIFTOUT(val, BWI_ID_HI_REGWIN_VENDOR_MASK)); } static void bwi_led_attach(struct bwi_softc *sc) { const uint8_t *led_act = NULL; uint16_t gpio, val[BWI_LED_MAX]; int i; for (i = 0; i < __arraycount(bwi_vendor_led_act); ++i) { if (sc->sc_pci_subvid == bwi_vendor_led_act[i].vid) { led_act = bwi_vendor_led_act[i].led_act; break; } } if (led_act == NULL) led_act = bwi_default_led_act; gpio = bwi_read_sprom(sc, BWI_SPROM_GPIO01); val[0] = __SHIFTOUT(gpio, BWI_SPROM_GPIO_0); val[1] = __SHIFTOUT(gpio, BWI_SPROM_GPIO_1); gpio = bwi_read_sprom(sc, BWI_SPROM_GPIO23); val[2] = __SHIFTOUT(gpio, BWI_SPROM_GPIO_2); val[3] = __SHIFTOUT(gpio, BWI_SPROM_GPIO_3); for (i = 0; i < BWI_LED_MAX; ++i) { struct bwi_led *led = &sc->sc_leds[i]; if (val[i] == 0xff) { led->l_act = led_act[i]; } else { if (val[i] & BWI_LED_ACT_LOW) led->l_flags |= BWI_LED_F_ACTLOW; led->l_act = __SHIFTOUT(val[i], BWI_LED_ACT_MASK); } led->l_mask = (1 << i); if (led->l_act == BWI_LED_ACT_BLINK_SLOW || led->l_act == BWI_LED_ACT_BLINK_POLL || led->l_act == BWI_LED_ACT_BLINK) { led->l_flags |= BWI_LED_F_BLINK; if (led->l_act == BWI_LED_ACT_BLINK_POLL) led->l_flags |= BWI_LED_F_POLLABLE; else if (led->l_act == BWI_LED_ACT_BLINK_SLOW) led->l_flags |= BWI_LED_F_SLOW; if (sc->sc_blink_led == NULL) { sc->sc_blink_led = led; if (led->l_flags & BWI_LED_F_SLOW) BWI_LED_SLOWDOWN(sc->sc_led_idle); } } DPRINTF(sc, BWI_DBG_LED | BWI_DBG_ATTACH, "%dth led, act %d, lowact %d\n", i, led->l_act, led->l_flags & BWI_LED_F_ACTLOW); } callout_init(&sc->sc_led_blink_ch, 0); } static uint16_t bwi_led_onoff(const struct bwi_led *led, uint16_t val, int on) { if (led->l_flags & BWI_LED_F_ACTLOW) on = !on; if (on) val |= led->l_mask; else val &= ~led->l_mask; return (val); } static void bwi_led_newstate(struct bwi_softc *sc, enum ieee80211_state nstate) { struct ieee80211com *ic = &sc->sc_ic; struct ifnet *ifp = &sc->sc_if; uint16_t val; int i; if (nstate == IEEE80211_S_INIT) { callout_stop(&sc->sc_led_blink_ch); sc->sc_led_blinking = 0; } if ((ifp->if_flags & IFF_RUNNING) == 0) return; val = CSR_READ_2(sc, BWI_MAC_GPIO_CTRL); for (i = 0; i < BWI_LED_MAX; ++i) { struct bwi_led *led = &sc->sc_leds[i]; int on; if (led->l_act == BWI_LED_ACT_UNKN || led->l_act == BWI_LED_ACT_NULL) continue; if ((led->l_flags & BWI_LED_F_BLINK) && nstate != IEEE80211_S_INIT) continue; switch (led->l_act) { case BWI_LED_ACT_ON: /* Always on */ on = 1; break; case BWI_LED_ACT_OFF: /* Always off */ case BWI_LED_ACT_5GHZ: /* TODO: 11A */ on = 0; break; default: on = 1; switch (nstate) { case IEEE80211_S_INIT: on = 0; break; case IEEE80211_S_RUN: if (led->l_act == BWI_LED_ACT_11G && ic->ic_curmode != IEEE80211_MODE_11G) on = 0; break; default: if (led->l_act == BWI_LED_ACT_ASSOC) on = 0; break; } break; } val = bwi_led_onoff(led, val, on); } CSR_WRITE_2(sc, BWI_MAC_GPIO_CTRL, val); } static void bwi_led_event(struct bwi_softc *sc, int event) { struct bwi_led *led = sc->sc_blink_led; int rate; if (event == BWI_LED_EVENT_POLL) { if ((led->l_flags & BWI_LED_F_POLLABLE) == 0) return; if (ticks - sc->sc_led_ticks < sc->sc_led_idle) return; } sc->sc_led_ticks = ticks; if (sc->sc_led_blinking) return; switch (event) { case BWI_LED_EVENT_RX: rate = sc->sc_rx_rate; break; case BWI_LED_EVENT_TX: rate = sc->sc_tx_rate; break; case BWI_LED_EVENT_POLL: rate = 0; break; default: panic("unknown LED event %d\n", event); break; } bwi_led_blink_start(sc, bwi_led_duration[rate].on_dur, bwi_led_duration[rate].off_dur); } static void bwi_led_blink_start(struct bwi_softc *sc, int on_dur, int off_dur) { struct bwi_led *led = sc->sc_blink_led; uint16_t val; val = CSR_READ_2(sc, BWI_MAC_GPIO_CTRL); val = bwi_led_onoff(led, val, 1); CSR_WRITE_2(sc, BWI_MAC_GPIO_CTRL, val); if (led->l_flags & BWI_LED_F_SLOW) { BWI_LED_SLOWDOWN(on_dur); BWI_LED_SLOWDOWN(off_dur); } sc->sc_led_blinking = 1; sc->sc_led_blink_offdur = off_dur; callout_reset(&sc->sc_led_blink_ch, on_dur, bwi_led_blink_next, sc); } static void bwi_led_blink_next(void *xsc) { struct bwi_softc *sc = xsc; uint16_t val; val = CSR_READ_2(sc, BWI_MAC_GPIO_CTRL); val = bwi_led_onoff(sc->sc_blink_led, val, 0); CSR_WRITE_2(sc, BWI_MAC_GPIO_CTRL, val); callout_reset(&sc->sc_led_blink_ch, sc->sc_led_blink_offdur, bwi_led_blink_end, sc); } static void bwi_led_blink_end(void *xsc) { struct bwi_softc *sc = xsc; sc->sc_led_blinking = 0; } static int bwi_bbp_attach(struct bwi_softc *sc) { uint16_t bbp_id, rw_type; uint8_t rw_rev; uint32_t info; int error, nregwin, i; /* * Get 0th regwin information * NOTE: 0th regwin should exist */ error = bwi_regwin_select(sc, 0); if (error) { aprint_error_dev(sc->sc_dev, "can't select regwin 0\n"); return (error); } bwi_regwin_info(sc, &rw_type, &rw_rev); /* * Find out BBP id */ bbp_id = 0; info = 0; if (rw_type == BWI_REGWIN_T_COM) { info = CSR_READ_4(sc, BWI_INFO); bbp_id = __SHIFTOUT(info, BWI_INFO_BBPID_MASK); BWI_CREATE_REGWIN(&sc->sc_com_regwin, 0, rw_type, rw_rev); sc->sc_cap = CSR_READ_4(sc, BWI_CAPABILITY); } else { uint16_t did = sc->sc_pci_did; uint8_t revid = sc->sc_pci_revid; for (i = 0; i < __arraycount(bwi_bbpid_map); ++i) { if (did >= bwi_bbpid_map[i].did_min && did <= bwi_bbpid_map[i].did_max) { bbp_id = bwi_bbpid_map[i].bbp_id; break; } } if (bbp_id == 0) { aprint_error_dev(sc->sc_dev, "no BBP id for device id" " 0x%04x\n", did); return (ENXIO); } info = __SHIFTIN(revid, BWI_INFO_BBPREV_MASK) | __SHIFTIN(0, BWI_INFO_BBPPKG_MASK); } /* * Find out number of regwins */ nregwin = 0; if (rw_type == BWI_REGWIN_T_COM && rw_rev >= 4) { nregwin = __SHIFTOUT(info, BWI_INFO_NREGWIN_MASK); } else { for (i = 0; i < __arraycount(bwi_regwin_count); ++i) { if (bwi_regwin_count[i].bbp_id == bbp_id) { nregwin = bwi_regwin_count[i].nregwin; break; } } if (nregwin == 0) { aprint_error_dev(sc->sc_dev, "no number of win for" " BBP id 0x%04x\n", bbp_id); return (ENXIO); } } /* Record BBP id/rev for later using */ sc->sc_bbp_id = bbp_id; sc->sc_bbp_rev = __SHIFTOUT(info, BWI_INFO_BBPREV_MASK); sc->sc_bbp_pkg = __SHIFTOUT(info, BWI_INFO_BBPPKG_MASK); aprint_normal_dev(sc->sc_dev, "BBP id 0x%04x, BBP rev 0x%x, BBP pkg %d\n", sc->sc_bbp_id, sc->sc_bbp_rev, sc->sc_bbp_pkg); DPRINTF(sc, BWI_DBG_ATTACH, "nregwin %d, cap 0x%08x\n", nregwin, sc->sc_cap); /* * Create rest of the regwins */ /* Don't re-create common regwin, if it is already created */ i = BWI_REGWIN_EXIST(&sc->sc_com_regwin) ? 1 : 0; for (; i < nregwin; ++i) { /* * Get regwin information */ error = bwi_regwin_select(sc, i); if (error) { aprint_error_dev(sc->sc_dev, "can't select regwin" " %d\n", i); return (error); } bwi_regwin_info(sc, &rw_type, &rw_rev); /* * Try attach: * 1) Bus (PCI/PCIE) regwin * 2) MAC regwin * Ignore rest types of regwin */ if (rw_type == BWI_REGWIN_T_BUSPCI || rw_type == BWI_REGWIN_T_BUSPCIE) { if (BWI_REGWIN_EXIST(&sc->sc_bus_regwin)) { aprint_error_dev(sc->sc_dev, "bus regwin already exists\n"); } else { BWI_CREATE_REGWIN(&sc->sc_bus_regwin, i, rw_type, rw_rev); } } else if (rw_type == BWI_REGWIN_T_MAC) { /* XXX ignore return value */ bwi_mac_attach(sc, i, rw_rev); } } /* At least one MAC shold exist */ if (!BWI_REGWIN_EXIST(&sc->sc_mac[0].mac_regwin)) { aprint_error_dev(sc->sc_dev, "no MAC was found\n"); return (ENXIO); } KASSERT(sc->sc_nmac > 0); /* Bus regwin must exist */ if (!BWI_REGWIN_EXIST(&sc->sc_bus_regwin)) { aprint_error_dev(sc->sc_dev, "no bus regwin was found\n"); return (ENXIO); } /* Start with first MAC */ error = bwi_regwin_switch(sc, &sc->sc_mac[0].mac_regwin, NULL); if (error) return (error); return (0); } static int bwi_bus_init(struct bwi_softc *sc, struct bwi_mac *mac) { struct bwi_regwin *old, *bus; uint32_t val; int error; bus = &sc->sc_bus_regwin; KASSERT(sc->sc_cur_regwin == &mac->mac_regwin); /* * Tell bus to generate requested interrupts */ if (bus->rw_rev < 6 && bus->rw_type == BWI_REGWIN_T_BUSPCI) { /* * NOTE: Read BWI_FLAGS from MAC regwin */ val = CSR_READ_4(sc, BWI_FLAGS); error = bwi_regwin_switch(sc, bus, &old); if (error) return (error); CSR_SETBITS_4(sc, BWI_INTRVEC, (val & BWI_FLAGS_INTR_MASK)); } else { uint32_t mac_mask; mac_mask = 1 << mac->mac_id; error = bwi_regwin_switch(sc, bus, &old); if (error) return (error); val = (sc->sc_conf_read)(sc, BWI_PCIR_INTCTL); val |= mac_mask << 8; (sc->sc_conf_write)(sc, BWI_PCIR_INTCTL, val); } if (sc->sc_flags & BWI_F_BUS_INITED) goto back; if (bus->rw_type == BWI_REGWIN_T_BUSPCI) { /* * Enable prefetch and burst */ CSR_SETBITS_4(sc, BWI_BUS_CONFIG, BWI_BUS_CONFIG_PREFETCH | BWI_BUS_CONFIG_BURST); if (bus->rw_rev < 5) { struct bwi_regwin *com = &sc->sc_com_regwin; /* * Configure timeouts for bus operation */ /* * Set service timeout and request timeout */ CSR_SETBITS_4(sc, BWI_CONF_LO, __SHIFTIN(BWI_CONF_LO_SERVTO, BWI_CONF_LO_SERVTO_MASK) | __SHIFTIN(BWI_CONF_LO_REQTO, BWI_CONF_LO_REQTO_MASK)); /* * If there is common regwin, we switch to that regwin * and switch back to bus regwin once we have done. */ if (BWI_REGWIN_EXIST(com)) { error = bwi_regwin_switch(sc, com, NULL); if (error) return (error); } /* Let bus know what we have changed */ CSR_WRITE_4(sc, BWI_BUS_ADDR, BWI_BUS_ADDR_MAGIC); CSR_READ_4(sc, BWI_BUS_ADDR); /* Flush */ CSR_WRITE_4(sc, BWI_BUS_DATA, 0); CSR_READ_4(sc, BWI_BUS_DATA); /* Flush */ if (BWI_REGWIN_EXIST(com)) { error = bwi_regwin_switch(sc, bus, NULL); if (error) return (error); } } else if (bus->rw_rev >= 11) { /* * Enable memory read multiple */ CSR_SETBITS_4(sc, BWI_BUS_CONFIG, BWI_BUS_CONFIG_MRM); } } else { /* TODO: PCIE */ } sc->sc_flags |= BWI_F_BUS_INITED; back: return (bwi_regwin_switch(sc, old, NULL)); } static void bwi_get_card_flags(struct bwi_softc *sc) { sc->sc_card_flags = bwi_read_sprom(sc, BWI_SPROM_CARD_FLAGS); if (sc->sc_card_flags == 0xffff) sc->sc_card_flags = 0; if (sc->sc_pci_subvid == PCI_VENDOR_APPLE && sc->sc_pci_subdid == 0x4e && /* XXX */ sc->sc_pci_revid > 0x40) sc->sc_card_flags |= BWI_CARD_F_PA_GPIO9; DPRINTF(sc, BWI_DBG_ATTACH, "card flags 0x%04x\n", sc->sc_card_flags); } static void bwi_get_eaddr(struct bwi_softc *sc, uint16_t eaddr_ofs, uint8_t *eaddr) { int i; for (i = 0; i < 3; ++i) { *((uint16_t *)eaddr + i) = htobe16(bwi_read_sprom(sc, eaddr_ofs + 2 * i)); } } static void bwi_get_clock_freq(struct bwi_softc *sc, struct bwi_clock_freq *freq) { struct bwi_regwin *com; uint32_t val; uint div; int src; memset(freq, 0, sizeof(*freq)); com = &sc->sc_com_regwin; KASSERT(BWI_REGWIN_EXIST(com)); KASSERT(sc->sc_cur_regwin == com); KASSERT(sc->sc_cap & BWI_CAP_CLKMODE); /* * Calculate clock frequency */ src = -1; div = 0; if (com->rw_rev < 6) { val = (sc->sc_conf_read)(sc, BWI_PCIR_GPIO_OUT); if (val & BWI_PCIM_GPIO_OUT_CLKSRC) { src = BWI_CLKSRC_PCI; div = 64; } else { src = BWI_CLKSRC_CS_OSC; div = 32; } } else if (com->rw_rev < 10) { val = CSR_READ_4(sc, BWI_CLOCK_CTRL); src = __SHIFTOUT(val, BWI_CLOCK_CTRL_CLKSRC); if (src == BWI_CLKSRC_LP_OSC) div = 1; else { div = (__SHIFTOUT(val, BWI_CLOCK_CTRL_FDIV) + 1) << 2; /* Unknown source */ if (src >= BWI_CLKSRC_MAX) src = BWI_CLKSRC_CS_OSC; } } else { val = CSR_READ_4(sc, BWI_CLOCK_INFO); src = BWI_CLKSRC_CS_OSC; div = (__SHIFTOUT(val, BWI_CLOCK_INFO_FDIV) + 1) << 2; } KASSERT(src >= 0 && src < BWI_CLKSRC_MAX); KASSERT(div != 0); DPRINTF(sc, BWI_DBG_ATTACH, "clksrc %s\n", src == BWI_CLKSRC_PCI ? "PCI" : (src == BWI_CLKSRC_LP_OSC ? "LP_OSC" : "CS_OSC")); freq->clkfreq_min = bwi_clkfreq[src].freq_min / div; freq->clkfreq_max = bwi_clkfreq[src].freq_max / div; DPRINTF(sc, BWI_DBG_ATTACH, "clkfreq min %u, max %u\n", freq->clkfreq_min, freq->clkfreq_max); } static int bwi_set_clock_mode(struct bwi_softc *sc, enum bwi_clock_mode clk_mode) { struct bwi_regwin *old, *com; uint32_t clk_ctrl, clk_src; int error, pwr_off = 0; com = &sc->sc_com_regwin; if (!BWI_REGWIN_EXIST(com)) return (0); if (com->rw_rev >= 10 || com->rw_rev < 6) return (0); /* * For common regwin whose rev is [6, 10), the chip * must be capable to change clock mode. */ if ((sc->sc_cap & BWI_CAP_CLKMODE) == 0) return (0); error = bwi_regwin_switch(sc, com, &old); if (error) return (error); if (clk_mode == BWI_CLOCK_MODE_FAST) bwi_power_on(sc, 0); /* Don't turn on PLL */ clk_ctrl = CSR_READ_4(sc, BWI_CLOCK_CTRL); clk_src = __SHIFTOUT(clk_ctrl, BWI_CLOCK_CTRL_CLKSRC); switch (clk_mode) { case BWI_CLOCK_MODE_FAST: clk_ctrl &= ~BWI_CLOCK_CTRL_SLOW; clk_ctrl |= BWI_CLOCK_CTRL_IGNPLL; break; case BWI_CLOCK_MODE_SLOW: clk_ctrl |= BWI_CLOCK_CTRL_SLOW; break; case BWI_CLOCK_MODE_DYN: clk_ctrl &= ~(BWI_CLOCK_CTRL_SLOW | BWI_CLOCK_CTRL_IGNPLL | BWI_CLOCK_CTRL_NODYN); if (clk_src != BWI_CLKSRC_CS_OSC) { clk_ctrl |= BWI_CLOCK_CTRL_NODYN; pwr_off = 1; } break; } CSR_WRITE_4(sc, BWI_CLOCK_CTRL, clk_ctrl); if (pwr_off) bwi_power_off(sc, 0); /* Leave PLL as it is */ return (bwi_regwin_switch(sc, old, NULL)); } static int bwi_set_clock_delay(struct bwi_softc *sc) { struct bwi_regwin *old, *com; int error; com = &sc->sc_com_regwin; if (!BWI_REGWIN_EXIST(com)) return (0); error = bwi_regwin_switch(sc, com, &old); if (error) return (error); if (sc->sc_bbp_id == BWI_BBPID_BCM4321) { if (sc->sc_bbp_rev == 0) CSR_WRITE_4(sc, BWI_CONTROL, BWI_CONTROL_MAGIC0); else if (sc->sc_bbp_rev == 1) CSR_WRITE_4(sc, BWI_CONTROL, BWI_CONTROL_MAGIC1); } if (sc->sc_cap & BWI_CAP_CLKMODE) { if (com->rw_rev >= 10) CSR_FILT_SETBITS_4(sc, BWI_CLOCK_INFO, 0xffff, 0x40000); else { struct bwi_clock_freq freq; bwi_get_clock_freq(sc, &freq); CSR_WRITE_4(sc, BWI_PLL_ON_DELAY, howmany(freq.clkfreq_max * 150, 1000000)); CSR_WRITE_4(sc, BWI_FREQ_SEL_DELAY, howmany(freq.clkfreq_max * 15, 1000000)); } } return (bwi_regwin_switch(sc, old, NULL)); } static int bwi_init(struct ifnet *ifp) { struct bwi_softc *sc = ifp->if_softc; bwi_init_statechg(sc, 1); return (0); } static void bwi_init_statechg(struct bwi_softc *sc, int statechg) { struct ieee80211com *ic = &sc->sc_ic; struct ifnet *ifp = &sc->sc_if; struct bwi_mac *mac; int error; DPRINTF(sc, BWI_DBG_MISC, "%s\n", __func__); bwi_stop(ifp, statechg); /* power on cardbus socket */ if (sc->sc_enable != NULL) (sc->sc_enable)(sc, 0); bwi_bbp_power_on(sc, BWI_CLOCK_MODE_FAST); /* TODO: 2 MAC */ mac = &sc->sc_mac[0]; error = bwi_regwin_switch(sc, &mac->mac_regwin, NULL); if (error) goto back; error = bwi_mac_init(mac); if (error) goto back; bwi_bbp_power_on(sc, BWI_CLOCK_MODE_DYN); IEEE80211_ADDR_COPY(ic->ic_myaddr, CLLADDR(ifp->if_sadl)); bwi_set_bssid(sc, bwi_zero_addr); /* Clear BSSID */ bwi_set_addr_filter(sc, BWI_ADDR_FILTER_MYADDR, ic->ic_myaddr); bwi_mac_reset_hwkeys(mac); if ((mac->mac_flags & BWI_MAC_F_HAS_TXSTATS) == 0) { int i; #define NRETRY 1000 /* * Drain any possible pending TX status */ for (i = 0; i < NRETRY; ++i) { if ((CSR_READ_4(sc, BWI_TXSTATUS_0) & BWI_TXSTATUS_0_MORE) == 0) break; CSR_READ_4(sc, BWI_TXSTATUS_1); } if (i == NRETRY) aprint_error_dev(sc->sc_dev, "can't drain TX status\n"); #undef NRETRY } if (mac->mac_phy.phy_mode == IEEE80211_MODE_11G) bwi_mac_updateslot(mac, 1); /* Start MAC */ error = bwi_mac_start(mac); if (error) goto back; /* Enable intrs */ bwi_enable_intrs(sc, BWI_INIT_INTRS); ifp->if_flags |= IFF_RUNNING; ifp->if_flags &= ~IFF_OACTIVE; if (statechg) { if (ic->ic_opmode != IEEE80211_M_MONITOR) { /* [TRC: XXX OpenBSD omits this conditional.] */ if (ic->ic_roaming != IEEE80211_ROAMING_MANUAL) ieee80211_new_state(ic, IEEE80211_S_SCAN, -1); } else { ieee80211_new_state(ic, IEEE80211_S_RUN, -1); } } else { ieee80211_new_state(ic, ic->ic_state, -1); } back: if (error) bwi_stop(ifp, 1); else /* [TRC: XXX DragonFlyBD uses ifp->if_start(ifp).] */ bwi_start(ifp); } static int bwi_ioctl(struct ifnet *ifp, u_long cmd, void *data) { struct bwi_softc *sc = ifp->if_softc; struct ieee80211com *ic = &sc->sc_ic; int s, error = 0; /* [TRC: XXX Superstitiously cargo-culted from wi(4).] */ if (!device_is_active(sc->sc_dev)) return (ENXIO); s = splnet(); switch (cmd) { case SIOCSIFFLAGS: if ((error = ifioctl_common(ifp, cmd, data)) != 0) break; if ((ifp->if_flags & (IFF_UP | IFF_RUNNING)) == (IFF_UP | IFF_RUNNING)) { struct bwi_mac *mac; int promisc = -1; KASSERT(sc->sc_cur_regwin->rw_type == BWI_REGWIN_T_MAC); mac = (struct bwi_mac *)sc->sc_cur_regwin; if ((ifp->if_flags & IFF_PROMISC) && (sc->sc_flags & BWI_F_PROMISC) == 0) { promisc = 1; sc->sc_flags |= BWI_F_PROMISC; } else if ((ifp->if_flags & IFF_PROMISC) == 0 && (sc->sc_flags & BWI_F_PROMISC)) { promisc = 0; sc->sc_flags &= ~BWI_F_PROMISC; } if (promisc >= 0) bwi_mac_set_promisc(mac, promisc); } if (ifp->if_flags & IFF_UP) { if (!(ifp->if_flags & IFF_RUNNING)) bwi_init(ifp); } else { if (ifp->if_flags & IFF_RUNNING) bwi_stop(ifp, 1); } break; case SIOCADDMULTI: case SIOCDELMULTI: /* [TRC: Several other drivers appear to have this copied & pasted, so I'm following suit.] */ /* XXX no h/w multicast filter? --dyoung */ if ((error = ether_ioctl(ifp, cmd, data)) == ENETRESET) { /* setup multicast filter, etc */ error = 0; } break; case SIOCS80211CHANNEL: /* [TRC: Pilfered from OpenBSD. No clue whether it works.] */ /* allow fast channel switching in monitor mode */ error = ieee80211_ioctl(ic, cmd, data); if (error == ENETRESET && ic->ic_opmode == IEEE80211_M_MONITOR) { if ((ifp->if_flags & (IFF_UP | IFF_RUNNING)) == (IFF_UP | IFF_RUNNING)) { /* [TRC: XXX ????] */ ic->ic_bss->ni_chan = ic->ic_ibss_chan; ic->ic_curchan = ic->ic_ibss_chan; bwi_set_chan(sc, ic->ic_bss->ni_chan); } error = 0; } break; default: error = ieee80211_ioctl(ic, cmd, data); break; } if (error == ENETRESET) { if ((ifp->if_flags & (IFF_UP | IFF_RUNNING)) == (IFF_UP | IFF_RUNNING) && /* [TRC: XXX Superstitiously cargo-culted from iwi(4). */ (ic->ic_roaming != IEEE80211_ROAMING_MANUAL)) bwi_init(ifp); error = 0; } splx(s); return (error); } static void bwi_start(struct ifnet *ifp) { struct bwi_softc *sc = ifp->if_softc; struct ieee80211com *ic = &sc->sc_ic; struct bwi_txbuf_data *tbd = &sc->sc_tx_bdata[BWI_TX_DATA_RING]; int trans, idx; /* [TRC: XXX I'm not sure under which conditions we're actually supposed to refuse to start, so I'm copying what OpenBSD and DragonFlyBSD do, even if no one else on NetBSD does it. */ if ((ifp->if_flags & IFF_OACTIVE) || (ifp->if_flags & IFF_RUNNING) == 0) return; trans = 0; idx = tbd->tbd_idx; while (tbd->tbd_buf[idx].tb_mbuf == NULL) { struct ieee80211_frame *wh; struct ieee80211_node *ni; struct mbuf *m; int mgt_pkt = 0; IF_DEQUEUE(&ic->ic_mgtq, m); if (m != NULL) { ni = M_GETCTX(m, struct ieee80211_node *); M_CLEARCTX(m); mgt_pkt = 1; } else { struct ether_header *eh; if (ic->ic_state != IEEE80211_S_RUN) break; IFQ_DEQUEUE(&ifp->if_snd, m); if (m == NULL) break; if (m->m_len < sizeof(*eh)) { m = m_pullup(m, sizeof(*eh)); if (m == NULL) { ifp->if_oerrors++; continue; } } eh = mtod(m, struct ether_header *); ni = ieee80211_find_txnode(ic, eh->ether_dhost); if (ni == NULL) { ifp->if_oerrors++; m_freem(m); continue; } /* [TRC: XXX Superstitiously cargo-culted from ath(4) and wi(4).] */ if ((ni->ni_flags & IEEE80211_NODE_PWR_MGT) && (m->m_flags & M_PWR_SAV) == 0) { ieee80211_pwrsave(ic, ni, m); ieee80211_free_node(ni); continue; } /* [TRC: XXX I *think* we're supposed to do this, but honestly I have no clue. We don't use M_WME_GETAC, so...] */ if (ieee80211_classify(ic, m, ni)) { /* [TRC: XXX What debug flag?] */ DPRINTF(sc, BWI_DBG_MISC, "%s: discard, classification failure\n", __func__); ifp->if_oerrors++; m_freem(m); ieee80211_free_node(ni); continue; } /* [TRC: XXX wi(4) and awi(4) do this; iwi(4) doesn't.] */ ifp->if_opackets++; /* [TRC: XXX When should the packet be filtered? Different drivers appear to do it at different times.] */ /* TODO: PS */ bpf_mtap(ifp, m); m = ieee80211_encap(ic, m, ni); if (m == NULL) { ifp->if_oerrors++; ieee80211_free_node(ni); continue; } } bpf_mtap3(ic->ic_rawbpf, m); wh = mtod(m, struct ieee80211_frame *); /* [TRC: XXX What about ic->ic_flags & IEEE80211_F_PRIVACY?] */ if (wh->i_fc[1] & IEEE80211_FC1_WEP) { if (ieee80211_crypto_encap(ic, ni, m) == NULL) { ifp->if_oerrors++; m_freem(m); ieee80211_free_node(ni); continue; } } wh = NULL; /* [TRC: XXX Huh?] */ if (bwi_encap(sc, idx, m, &ni, mgt_pkt) != 0) { /* 'm' is freed in bwi_encap() if we reach here */ ifp->if_oerrors++; if (ni != NULL) ieee80211_free_node(ni); continue; } trans = 1; tbd->tbd_used++; idx = (idx + 1) % BWI_TX_NDESC; if (tbd->tbd_used + BWI_TX_NSPRDESC >= BWI_TX_NDESC) { ifp->if_flags |= IFF_OACTIVE; break; } } tbd->tbd_idx = idx; if (trans) sc->sc_tx_timer = 5; ifp->if_timer = 1; } static void bwi_watchdog(struct ifnet *ifp) { struct bwi_softc *sc = ifp->if_softc; ifp->if_timer = 0; if ((ifp->if_flags & IFF_RUNNING) == 0 || !device_is_active(sc->sc_dev)) return; if (sc->sc_tx_timer) { if (--sc->sc_tx_timer == 0) { aprint_error_dev(sc->sc_dev, "device timeout\n"); ifp->if_oerrors++; /* TODO */ /* [TRC: XXX TODO what? Stop the device? Bring it down? iwi(4) does this.] */ } else ifp->if_timer = 1; } ieee80211_watchdog(&sc->sc_ic); } static void bwi_stop(struct ifnet *ifp, int state_chg) { struct bwi_softc *sc = ifp->if_softc; struct ieee80211com *ic = &sc->sc_ic; struct bwi_mac *mac; int i, error, pwr_off = 0; DPRINTF(sc, BWI_DBG_MISC, "%s\n", __func__); if (state_chg) ieee80211_new_state(ic, IEEE80211_S_INIT, -1); else bwi_newstate_begin(sc, IEEE80211_S_INIT); if (ifp->if_flags & IFF_RUNNING) { KASSERT(sc->sc_cur_regwin->rw_type == BWI_REGWIN_T_MAC); mac = (struct bwi_mac *)sc->sc_cur_regwin; bwi_disable_intrs(sc, BWI_ALL_INTRS); CSR_READ_4(sc, BWI_MAC_INTR_MASK); bwi_mac_stop(mac); } for (i = 0; i < sc->sc_nmac; ++i) { struct bwi_regwin *old_rw; mac = &sc->sc_mac[i]; if ((mac->mac_flags & BWI_MAC_F_INITED) == 0) continue; error = bwi_regwin_switch(sc, &mac->mac_regwin, &old_rw); if (error) continue; bwi_mac_shutdown(mac); pwr_off = 1; bwi_regwin_switch(sc, old_rw, NULL); } if (pwr_off) bwi_bbp_power_off(sc); sc->sc_tx_timer = 0; ifp->if_timer = 0; ifp->if_flags &= ~(IFF_RUNNING | IFF_OACTIVE); /* power off cardbus socket */ if (sc->sc_disable != NULL) (sc->sc_disable)(sc, 0); return; } static void bwi_newstate_begin(struct bwi_softc *sc, enum ieee80211_state nstate) { callout_stop(&sc->sc_scan_ch); callout_stop(&sc->sc_calib_ch); bwi_led_newstate(sc, nstate); if (nstate == IEEE80211_S_INIT) sc->sc_txpwrcb_type = BWI_TXPWR_INIT; } static int bwi_newstate(struct ieee80211com *ic, enum ieee80211_state nstate, int arg) { struct bwi_softc *sc = ic->ic_ifp->if_softc; struct ieee80211_node *ni; int error; /* [TRC: XXX amrr] */ callout_stop(&sc->sc_amrr_ch); bwi_newstate_begin(sc, nstate); if (nstate == IEEE80211_S_INIT) goto back; /* [TRC: XXX What channel do we set this to? */ error = bwi_set_chan(sc, ic->ic_curchan); if (error) { aprint_error_dev(sc->sc_dev, "can't set channel to %u\n", ieee80211_chan2ieee(ic, ic->ic_curchan)); return (error); } if (ic->ic_opmode == IEEE80211_M_MONITOR) { /* Nothing to do */ } else if (nstate == IEEE80211_S_RUN) { struct bwi_mac *mac; ni = ic->ic_bss; bwi_set_bssid(sc, ic->ic_bss->ni_bssid); KASSERT(sc->sc_cur_regwin->rw_type == BWI_REGWIN_T_MAC); mac = (struct bwi_mac *)sc->sc_cur_regwin; /* Initial TX power calibration */ bwi_mac_calibrate_txpower(mac, BWI_TXPWR_INIT); #ifdef notyet sc->sc_txpwrcb_type = BWI_TXPWR_FORCE; #else sc->sc_txpwrcb_type = BWI_TXPWR_CALIB; #endif /* [TRC: XXX amrr] */ if (ic->ic_opmode == IEEE80211_M_STA) { /* fake a join to init the tx rate */ bwi_newassoc(ni, 1); } if (ic->ic_opmode != IEEE80211_M_MONITOR) { /* start automatic rate control timer */ if (ic->ic_fixed_rate == -1) callout_schedule(&sc->sc_amrr_ch, hz / 2); } } else bwi_set_bssid(sc, bwi_zero_addr); back: error = (sc->sc_newstate)(ic, nstate, arg); if (nstate == IEEE80211_S_SCAN) { callout_schedule(&sc->sc_scan_ch, (sc->sc_dwell_time * hz) / 1000); } else if (nstate == IEEE80211_S_RUN) { /* XXX 15 seconds */ callout_schedule(&sc->sc_calib_ch, hz); } return (error); } static int bwi_media_change(struct ifnet *ifp) { int error; error = ieee80211_media_change(ifp); if (error != ENETRESET) return (error); if ((ifp->if_flags & (IFF_UP | IFF_RUNNING)) == (IFF_UP | IFF_RUNNING)) bwi_init(ifp); return (0); } /* [TRC: XXX amrr] */ static void bwi_iter_func(void *arg, struct ieee80211_node *ni) { struct bwi_softc *sc = arg; struct bwi_node *bn = (struct bwi_node *)ni; ieee80211_amrr_choose(&sc->sc_amrr, ni, &bn->amn); } static void bwi_amrr_timeout(void *arg) { struct bwi_softc *sc = arg; struct ieee80211com *ic = &sc->sc_ic; int s; s = splnet(); if (ic->ic_opmode == IEEE80211_M_STA) bwi_iter_func(sc, ic->ic_bss); else /* [TRC: XXX I'm making a wild guess about what to supply for the node table.] */ ieee80211_iterate_nodes(&ic->ic_sta, bwi_iter_func, sc); callout_schedule(&sc->sc_amrr_ch, hz / 2); splx(s); } static void bwi_newassoc(struct ieee80211_node *ni, int isnew) { struct ieee80211com *ic = ni->ni_ic; struct bwi_softc *sc = ic->ic_ifp->if_softc; int i; DPRINTF(sc, BWI_DBG_STATION, "%s\n", __func__); ieee80211_amrr_node_init(&sc->sc_amrr, &((struct bwi_node *)ni)->amn); /* set rate to some reasonable initial value */ for (i = ni->ni_rates.rs_nrates - 1; i > 0 && (ni->ni_rates.rs_rates[i] & IEEE80211_RATE_VAL) > 72; i--); ni->ni_txrate = i; } static struct ieee80211_node * bwi_node_alloc(struct ieee80211_node_table *nt) { struct bwi_node *bn; bn = malloc(sizeof(struct bwi_node), M_80211_NODE, M_NOWAIT | M_ZERO); return ((struct ieee80211_node *)bn); } /* [TRC: XXX amrr end] */ static int bwi_dma_alloc(struct bwi_softc *sc) { int error, i, has_txstats; /* [TRC: XXX DragonFlyBSD adjusts the low address for different bus spaces. Should we?] */ bus_size_t tx_ring_sz, rx_ring_sz, desc_sz = 0; uint32_t txrx_ctrl_step = 0; has_txstats = 0; for (i = 0; i < sc->sc_nmac; ++i) { if (sc->sc_mac[i].mac_flags & BWI_MAC_F_HAS_TXSTATS) { has_txstats = 1; break; } } switch (sc->sc_bus_space) { case BWI_BUS_SPACE_30BIT: case BWI_BUS_SPACE_32BIT: desc_sz = sizeof(struct bwi_desc32); txrx_ctrl_step = 0x20; sc->sc_init_tx_ring = bwi_init_tx_ring32; sc->sc_free_tx_ring = bwi_free_tx_ring32; sc->sc_init_rx_ring = bwi_init_rx_ring32; sc->sc_free_rx_ring = bwi_free_rx_ring32; sc->sc_setup_rxdesc = bwi_setup_rx_desc32; sc->sc_setup_txdesc = bwi_setup_tx_desc32; sc->sc_rxeof = bwi_rxeof32; sc->sc_start_tx = bwi_start_tx32; if (has_txstats) { sc->sc_init_txstats = bwi_init_txstats32; sc->sc_free_txstats = bwi_free_txstats32; sc->sc_txeof_status = bwi_txeof_status32; } break; case BWI_BUS_SPACE_64BIT: desc_sz = sizeof(struct bwi_desc64); txrx_ctrl_step = 0x40; sc->sc_init_tx_ring = bwi_init_tx_ring64; sc->sc_free_tx_ring = bwi_free_tx_ring64; sc->sc_init_rx_ring = bwi_init_rx_ring64; sc->sc_free_rx_ring = bwi_free_rx_ring64; sc->sc_setup_rxdesc = bwi_setup_rx_desc64; sc->sc_setup_txdesc = bwi_setup_tx_desc64; sc->sc_rxeof = bwi_rxeof64; sc->sc_start_tx = bwi_start_tx64; if (has_txstats) { sc->sc_init_txstats = bwi_init_txstats64; sc->sc_free_txstats = bwi_free_txstats64; sc->sc_txeof_status = bwi_txeof_status64; } break; } KASSERT(desc_sz != 0); KASSERT(txrx_ctrl_step != 0); tx_ring_sz = roundup(desc_sz * BWI_TX_NDESC, BWI_RING_ALIGN); rx_ring_sz = roundup(desc_sz * BWI_RX_NDESC, BWI_RING_ALIGN); /* [TRC: XXX Using OpenBSD's code, which is rather different from DragonFlyBSD's.] */ #define TXRX_CTRL(idx) (BWI_TXRX_CTRL_BASE + (idx) * txrx_ctrl_step) /* * Create TX ring DMA stuffs */ for (i = 0; i < BWI_TX_NRING; ++i) { error = bus_dmamap_create(sc->sc_dmat, tx_ring_sz, 1, tx_ring_sz, 0, BUS_DMA_NOWAIT, &sc->sc_tx_rdata[i].rdata_dmap); if (error) { aprint_error_dev(sc->sc_dev, "%dth TX ring DMA create failed\n", i); return (error); } error = bwi_dma_ring_alloc(sc, &sc->sc_tx_rdata[i], tx_ring_sz, TXRX_CTRL(i)); if (error) { aprint_error_dev(sc->sc_dev, "%dth TX ring DMA alloc failed\n", i); return (error); } } /* * Create RX ring DMA stuffs */ error = bus_dmamap_create(sc->sc_dmat, rx_ring_sz, 1, rx_ring_sz, 0, BUS_DMA_NOWAIT, &sc->sc_rx_rdata.rdata_dmap); if (error) { aprint_error_dev(sc->sc_dev, "RX ring DMA create failed\n"); return (error); } error = bwi_dma_ring_alloc(sc, &sc->sc_rx_rdata, rx_ring_sz, TXRX_CTRL(0)); if (error) { aprint_error_dev(sc->sc_dev, "RX ring DMA alloc failed\n"); return (error); } if (has_txstats) { error = bwi_dma_txstats_alloc(sc, TXRX_CTRL(3), desc_sz); if (error) { aprint_error_dev(sc->sc_dev, "TX stats DMA alloc failed\n"); return (error); } } #undef TXRX_CTRL return (bwi_dma_mbuf_create(sc)); } static void bwi_dma_free(struct bwi_softc *sc) { int i; for (i = 0; i < BWI_TX_NRING; ++i) bwi_ring_data_free(&sc->sc_tx_rdata[i], sc); bwi_ring_data_free(&sc->sc_rx_rdata, sc); bwi_dma_txstats_free(sc); bwi_dma_mbuf_destroy(sc, BWI_TX_NRING, 1); } static void bwi_ring_data_free(struct bwi_ring_data *rd, struct bwi_softc *sc) { if (rd->rdata_desc != NULL) { bus_dmamap_unload(sc->sc_dmat, rd->rdata_dmap); bus_dmamem_free(sc->sc_dmat, &rd->rdata_seg, 1); } } static int bwi_dma_ring_alloc(struct bwi_softc *sc, struct bwi_ring_data *rd, bus_size_t size, uint32_t txrx_ctrl) { int error, nsegs; error = bus_dmamem_alloc(sc->sc_dmat, size, BWI_ALIGN, 0, &rd->rdata_seg, 1, &nsegs, BUS_DMA_NOWAIT); if (error) { aprint_error_dev(sc->sc_dev, "can't allocate DMA mem\n"); return (error); } error = bus_dmamem_map(sc->sc_dmat, &rd->rdata_seg, nsegs, size, (void **)&rd->rdata_desc, BUS_DMA_NOWAIT); if (error) { aprint_error_dev(sc->sc_dev, "can't map DMA mem\n"); return (error); } error = bus_dmamap_load(sc->sc_dmat, rd->rdata_dmap, rd->rdata_desc, size, NULL, BUS_DMA_WAITOK); if (error) { aprint_error_dev(sc->sc_dev, "can't load DMA mem\n"); bus_dmamem_free(sc->sc_dmat, &rd->rdata_seg, nsegs); rd->rdata_desc = NULL; return (error); } rd->rdata_paddr = rd->rdata_dmap->dm_segs[0].ds_addr; rd->rdata_txrx_ctrl = txrx_ctrl; return (0); } static int bwi_dma_txstats_alloc(struct bwi_softc *sc, uint32_t ctrl_base, bus_size_t desc_sz) { struct bwi_txstats_data *st; bus_size_t dma_size; int error, nsegs; st = malloc(sizeof(*st), M_DEVBUF, M_WAITOK | M_ZERO); sc->sc_txstats = st; /* * Create TX stats descriptor DMA stuffs */ dma_size = roundup(desc_sz * BWI_TXSTATS_NDESC, BWI_RING_ALIGN); error = bus_dmamap_create(sc->sc_dmat, dma_size, 1, dma_size, 0, BUS_DMA_NOWAIT, &st->stats_ring_dmap); if (error) { aprint_error_dev(sc->sc_dev, "can't create txstats ring DMA mem\n"); return (error); } error = bus_dmamem_alloc(sc->sc_dmat, dma_size, BWI_RING_ALIGN, 0, &st->stats_ring_seg, 1, &nsegs, BUS_DMA_NOWAIT); if (error) { aprint_error_dev(sc->sc_dev, "can't allocate txstats ring DMA mem\n"); return (error); } error = bus_dmamem_map(sc->sc_dmat, &st->stats_ring_seg, nsegs, dma_size, (void **)&st->stats_ring, BUS_DMA_NOWAIT); if (error) { aprint_error_dev(sc->sc_dev, "can't map txstats ring DMA mem\n"); return (error); } error = bus_dmamap_load(sc->sc_dmat, st->stats_ring_dmap, st->stats_ring, dma_size, NULL, BUS_DMA_WAITOK); if (error) { aprint_error_dev(sc->sc_dev, "can't load txstats ring DMA mem\n"); bus_dmamem_free(sc->sc_dmat, &st->stats_ring_seg, nsegs); return (error); } memset(st->stats_ring, 0, dma_size); st->stats_ring_paddr = st->stats_ring_dmap->dm_segs[0].ds_addr; /* * Create TX stats DMA stuffs */ dma_size = roundup(sizeof(struct bwi_txstats) * BWI_TXSTATS_NDESC, BWI_ALIGN); error = bus_dmamap_create(sc->sc_dmat, dma_size, 1, dma_size, 0, BUS_DMA_NOWAIT, &st->stats_dmap); if (error) { aprint_error_dev(sc->sc_dev, "can't create txstats ring DMA mem\n"); return (error); } error = bus_dmamem_alloc(sc->sc_dmat, dma_size, BWI_ALIGN, 0, &st->stats_seg, 1, &nsegs, BUS_DMA_NOWAIT); if (error) { aprint_error_dev(sc->sc_dev, "can't allocate txstats DMA mem\n"); return (error); } error = bus_dmamem_map(sc->sc_dmat, &st->stats_seg, nsegs, dma_size, (void **)&st->stats, BUS_DMA_NOWAIT); if (error) { aprint_error_dev(sc->sc_dev, "can't map txstats DMA mem\n"); return (error); } error = bus_dmamap_load(sc->sc_dmat, st->stats_dmap, st->stats, dma_size, NULL, BUS_DMA_WAITOK); if (error) { aprint_error_dev(sc->sc_dev, "can't load txstats DMA mem\n"); bus_dmamem_free(sc->sc_dmat, &st->stats_seg, nsegs); return (error); } memset(st->stats, 0, dma_size); st->stats_paddr = st->stats_dmap->dm_segs[0].ds_addr; st->stats_ctrl_base = ctrl_base; return (0); } static void bwi_dma_txstats_free(struct bwi_softc *sc) { struct bwi_txstats_data *st; if (sc->sc_txstats == NULL) return; st = sc->sc_txstats; bus_dmamap_unload(sc->sc_dmat, st->stats_ring_dmap); bus_dmamem_free(sc->sc_dmat, &st->stats_ring_seg, 1); bus_dmamap_unload(sc->sc_dmat, st->stats_dmap); bus_dmamem_free(sc->sc_dmat, &st->stats_seg, 1); free(st, M_DEVBUF); } static int bwi_dma_mbuf_create(struct bwi_softc *sc) { struct bwi_rxbuf_data *rbd = &sc->sc_rx_bdata; int i, j, k, ntx, error; ntx = 0; /* * Create TX mbuf DMA map */ for (i = 0; i < BWI_TX_NRING; ++i) { struct bwi_txbuf_data *tbd = &sc->sc_tx_bdata[i]; for (j = 0; j < BWI_TX_NDESC; ++j) { error = bus_dmamap_create(sc->sc_dmat, MCLBYTES, 1, MCLBYTES, 0, BUS_DMA_NOWAIT, &tbd->tbd_buf[j].tb_dmap); if (error) { aprint_error_dev(sc->sc_dev, "can't create %dth tbd, %dth DMA map\n", i, j); ntx = i; for (k = 0; k < j; ++k) { bus_dmamap_destroy(sc->sc_dmat, tbd->tbd_buf[k].tb_dmap); } goto fail; } } } ntx = BWI_TX_NRING; /* * Create RX mbuf DMA map and a spare DMA map */ error = bus_dmamap_create(sc->sc_dmat, MCLBYTES, 1, MCLBYTES, 0, BUS_DMA_NOWAIT, &rbd->rbd_tmp_dmap); if (error) { aprint_error_dev(sc->sc_dev, "can't create spare RX buf DMA map\n"); goto fail; } for (j = 0; j < BWI_RX_NDESC; ++j) { error = bus_dmamap_create(sc->sc_dmat, MCLBYTES, 1, MCLBYTES, 0, BUS_DMA_NOWAIT, &rbd->rbd_buf[j].rb_dmap); if (error) { aprint_error_dev(sc->sc_dev, "can't create %dth RX buf DMA map\n", j); for (k = 0; k < j; ++k) { bus_dmamap_destroy(sc->sc_dmat, rbd->rbd_buf[j].rb_dmap); } bus_dmamap_destroy(sc->sc_dmat, rbd->rbd_tmp_dmap); goto fail; } } return (0); fail: bwi_dma_mbuf_destroy(sc, ntx, 0); return (error); } static void bwi_dma_mbuf_destroy(struct bwi_softc *sc, int ntx, int nrx) { int i, j; for (i = 0; i < ntx; ++i) { struct bwi_txbuf_data *tbd = &sc->sc_tx_bdata[i]; for (j = 0; j < BWI_TX_NDESC; ++j) { struct bwi_txbuf *tb = &tbd->tbd_buf[j]; if (tb->tb_mbuf != NULL) { bus_dmamap_unload(sc->sc_dmat, tb->tb_dmap); m_freem(tb->tb_mbuf); } if (tb->tb_ni != NULL) ieee80211_free_node(tb->tb_ni); bus_dmamap_destroy(sc->sc_dmat, tb->tb_dmap); } } if (nrx) { struct bwi_rxbuf_data *rbd = &sc->sc_rx_bdata; bus_dmamap_destroy(sc->sc_dmat, rbd->rbd_tmp_dmap); for (j = 0; j < BWI_RX_NDESC; ++j) { struct bwi_rxbuf *rb = &rbd->rbd_buf[j]; if (rb->rb_mbuf != NULL) { bus_dmamap_unload(sc->sc_dmat, rb->rb_dmap); m_freem(rb->rb_mbuf); } bus_dmamap_destroy(sc->sc_dmat, rb->rb_dmap); } } } static void bwi_enable_intrs(struct bwi_softc *sc, uint32_t enable_intrs) { CSR_SETBITS_4(sc, BWI_MAC_INTR_MASK, enable_intrs); } static void bwi_disable_intrs(struct bwi_softc *sc, uint32_t disable_intrs) { CSR_CLRBITS_4(sc, BWI_MAC_INTR_MASK, disable_intrs); } static int bwi_init_tx_ring32(struct bwi_softc *sc, int ring_idx) { struct bwi_ring_data *rd; struct bwi_txbuf_data *tbd; uint32_t val, addr_hi, addr_lo; KASSERT(ring_idx < BWI_TX_NRING); rd = &sc->sc_tx_rdata[ring_idx]; tbd = &sc->sc_tx_bdata[ring_idx]; tbd->tbd_idx = 0; tbd->tbd_used = 0; memset(rd->rdata_desc, 0, sizeof(struct bwi_desc32) * BWI_TX_NDESC); bus_dmamap_sync(sc->sc_dmat, rd->rdata_dmap, 0, rd->rdata_dmap->dm_mapsize, BUS_DMASYNC_PREWRITE); addr_lo = __SHIFTOUT(rd->rdata_paddr, BWI_TXRX32_RINGINFO_ADDR_MASK); addr_hi = __SHIFTOUT(rd->rdata_paddr, BWI_TXRX32_RINGINFO_FUNC_MASK); val = __SHIFTIN(addr_lo, BWI_TXRX32_RINGINFO_ADDR_MASK) | __SHIFTIN(BWI_TXRX32_RINGINFO_FUNC_TXRX, BWI_TXRX32_RINGINFO_FUNC_MASK); CSR_WRITE_4(sc, rd->rdata_txrx_ctrl + BWI_TX32_RINGINFO, val); val = __SHIFTIN(addr_hi, BWI_TXRX32_CTRL_ADDRHI_MASK) | BWI_TXRX32_CTRL_ENABLE; CSR_WRITE_4(sc, rd->rdata_txrx_ctrl + BWI_TX32_CTRL, val); return (0); } static void bwi_init_rxdesc_ring32(struct bwi_softc *sc, uint32_t ctrl_base, bus_addr_t paddr, int hdr_size, int ndesc) { uint32_t val, addr_hi, addr_lo; addr_lo = __SHIFTOUT(paddr, BWI_TXRX32_RINGINFO_ADDR_MASK); addr_hi = __SHIFTOUT(paddr, BWI_TXRX32_RINGINFO_FUNC_MASK); val = __SHIFTIN(addr_lo, BWI_TXRX32_RINGINFO_ADDR_MASK) | __SHIFTIN(BWI_TXRX32_RINGINFO_FUNC_TXRX, BWI_TXRX32_RINGINFO_FUNC_MASK); CSR_WRITE_4(sc, ctrl_base + BWI_RX32_RINGINFO, val); val = __SHIFTIN(hdr_size, BWI_RX32_CTRL_HDRSZ_MASK) | __SHIFTIN(addr_hi, BWI_TXRX32_CTRL_ADDRHI_MASK) | BWI_TXRX32_CTRL_ENABLE; CSR_WRITE_4(sc, ctrl_base + BWI_RX32_CTRL, val); CSR_WRITE_4(sc, ctrl_base + BWI_RX32_INDEX, (ndesc - 1) * sizeof(struct bwi_desc32)); } static int bwi_init_rx_ring32(struct bwi_softc *sc) { struct bwi_ring_data *rd = &sc->sc_rx_rdata; int i, error; sc->sc_rx_bdata.rbd_idx = 0; for (i = 0; i < BWI_RX_NDESC; ++i) { error = bwi_newbuf(sc, i, 1); if (error) { aprint_error_dev(sc->sc_dev, "can't allocate %dth RX buffer\n", i); return (error); } } bus_dmamap_sync(sc->sc_dmat, rd->rdata_dmap, 0, rd->rdata_dmap->dm_mapsize, BUS_DMASYNC_PREWRITE); bwi_init_rxdesc_ring32(sc, rd->rdata_txrx_ctrl, rd->rdata_paddr, sizeof(struct bwi_rxbuf_hdr), BWI_RX_NDESC); return (0); } static int bwi_init_txstats32(struct bwi_softc *sc) { struct bwi_txstats_data *st = sc->sc_txstats; bus_addr_t stats_paddr; int i; memset(st->stats, 0, BWI_TXSTATS_NDESC * sizeof(struct bwi_txstats)); bus_dmamap_sync(sc->sc_dmat, st->stats_dmap, 0, st->stats_dmap->dm_mapsize, BUS_DMASYNC_PREWRITE); st->stats_idx = 0; stats_paddr = st->stats_paddr; for (i = 0; i < BWI_TXSTATS_NDESC; ++i) { bwi_setup_desc32(sc, st->stats_ring, BWI_TXSTATS_NDESC, i, stats_paddr, sizeof(struct bwi_txstats), 0); stats_paddr += sizeof(struct bwi_txstats); } bus_dmamap_sync(sc->sc_dmat, st->stats_ring_dmap, 0, st->stats_ring_dmap->dm_mapsize, BUS_DMASYNC_PREWRITE); bwi_init_rxdesc_ring32(sc, st->stats_ctrl_base, st->stats_ring_paddr, 0, BWI_TXSTATS_NDESC); return (0); } static void bwi_setup_rx_desc32(struct bwi_softc *sc, int buf_idx, bus_addr_t paddr, int buf_len) { struct bwi_ring_data *rd = &sc->sc_rx_rdata; KASSERT(buf_idx < BWI_RX_NDESC); bwi_setup_desc32(sc, rd->rdata_desc, BWI_RX_NDESC, buf_idx, paddr, buf_len, 0); } static void bwi_setup_tx_desc32(struct bwi_softc *sc, struct bwi_ring_data *rd, int buf_idx, bus_addr_t paddr, int buf_len) { KASSERT(buf_idx < BWI_TX_NDESC); bwi_setup_desc32(sc, rd->rdata_desc, BWI_TX_NDESC, buf_idx, paddr, buf_len, 1); } static int bwi_init_tx_ring64(struct bwi_softc *sc, int ring_idx) { /* TODO: 64 */ return (EOPNOTSUPP); } static int bwi_init_rx_ring64(struct bwi_softc *sc) { /* TODO: 64 */ return (EOPNOTSUPP); } static int bwi_init_txstats64(struct bwi_softc *sc) { /* TODO: 64 */ return (EOPNOTSUPP); } static void bwi_setup_rx_desc64(struct bwi_softc *sc, int buf_idx, bus_addr_t paddr, int buf_len) { /* TODO: 64 */ } static void bwi_setup_tx_desc64(struct bwi_softc *sc, struct bwi_ring_data *rd, int buf_idx, bus_addr_t paddr, int buf_len) { /* TODO: 64 */ } static int bwi_newbuf(struct bwi_softc *sc, int buf_idx, int init) { struct bwi_rxbuf_data *rbd = &sc->sc_rx_bdata; struct bwi_rxbuf *rxbuf = &rbd->rbd_buf[buf_idx]; struct bwi_rxbuf_hdr *hdr; bus_dmamap_t map; bus_addr_t paddr; struct mbuf *m; int error; KASSERT(buf_idx < BWI_RX_NDESC); MGETHDR(m, init ? M_WAITOK : M_DONTWAIT, MT_DATA); if (m == NULL) return (ENOBUFS); MCLGET(m, init ? M_WAITOK : M_DONTWAIT); if ((m->m_flags & M_EXT) == 0) { error = ENOBUFS; /* * If the NIC is up and running, we need to: * - Clear RX buffer's header. * - Restore RX descriptor settings. */ if (init) return error; else goto back; } m->m_len = m->m_pkthdr.len = MCLBYTES; /* * Try to load RX buf into temporary DMA map */ error = bus_dmamap_load_mbuf(sc->sc_dmat, rbd->rbd_tmp_dmap, m, init ? BUS_DMA_WAITOK : BUS_DMA_NOWAIT); if (error) { m_freem(m); /* * See the comment above */ if (init) return error; else goto back; } if (!init) bus_dmamap_unload(sc->sc_dmat, rxbuf->rb_dmap); rxbuf->rb_mbuf = m; /* * Swap RX buf's DMA map with the loaded temporary one */ map = rxbuf->rb_dmap; rxbuf->rb_dmap = rbd->rbd_tmp_dmap; rbd->rbd_tmp_dmap = map; paddr = rxbuf->rb_dmap->dm_segs[0].ds_addr; rxbuf->rb_paddr = paddr; back: /* * Clear RX buf header */ hdr = mtod(rxbuf->rb_mbuf, struct bwi_rxbuf_hdr *); memset(hdr, 0, sizeof(*hdr)); bus_dmamap_sync(sc->sc_dmat, rxbuf->rb_dmap, 0, rxbuf->rb_dmap->dm_mapsize, BUS_DMASYNC_PREWRITE); /* * Setup RX buf descriptor */ (sc->sc_setup_rxdesc)(sc, buf_idx, rxbuf->rb_paddr, rxbuf->rb_mbuf->m_len - sizeof(*hdr)); return error; } static void bwi_set_addr_filter(struct bwi_softc *sc, uint16_t addr_ofs, const uint8_t *addr) { int i; CSR_WRITE_2(sc, BWI_ADDR_FILTER_CTRL, BWI_ADDR_FILTER_CTRL_SET | addr_ofs); for (i = 0; i < (IEEE80211_ADDR_LEN / 2); ++i) { uint16_t addr_val; addr_val = (uint16_t)addr[i * 2] | (((uint16_t)addr[(i * 2) + 1]) << 8); CSR_WRITE_2(sc, BWI_ADDR_FILTER_DATA, addr_val); } } static int bwi_set_chan(struct bwi_softc *sc, struct ieee80211_channel *c) { struct ieee80211com *ic = &sc->sc_ic; struct bwi_mac *mac; /* uint16_t flags; */ /* [TRC: XXX See below.] */ uint chan; KASSERT(sc->sc_cur_regwin->rw_type == BWI_REGWIN_T_MAC); mac = (struct bwi_mac *)sc->sc_cur_regwin; chan = ieee80211_chan2ieee(ic, c); bwi_rf_set_chan(mac, chan, 0); /* [TRC: XXX DragonFlyBSD sets up radio tap channel frequency and flags here. OpenBSD does not, and appears to do so later (in bwi_rxeof and bwi_encap).] */ return (0); } static void bwi_next_scan(void *xsc) { struct bwi_softc *sc = xsc; struct ieee80211com *ic = &sc->sc_ic; int s; s = splnet(); if (ic->ic_state == IEEE80211_S_SCAN) ieee80211_next_scan(ic); splx(s); } static int bwi_rxeof(struct bwi_softc *sc, int end_idx) { struct bwi_ring_data *rd = &sc->sc_rx_rdata; struct bwi_rxbuf_data *rbd = &sc->sc_rx_bdata; struct ieee80211com *ic = &sc->sc_ic; struct ifnet *ifp = &sc->sc_if; int s, idx, rx_data = 0; idx = rbd->rbd_idx; while (idx != end_idx) { struct bwi_rxbuf *rb = &rbd->rbd_buf[idx]; struct bwi_rxbuf_hdr *hdr; struct ieee80211_frame_min *wh; struct ieee80211_node *ni; struct mbuf *m; const void *plcp; uint16_t flags2; int buflen, wh_ofs, hdr_extra, rssi, type, rate; m = rb->rb_mbuf; bus_dmamap_sync(sc->sc_dmat, rb->rb_dmap, 0, rb->rb_dmap->dm_mapsize, BUS_DMASYNC_POSTREAD); if (bwi_newbuf(sc, idx, 0)) { ifp->if_ierrors++; goto next; } hdr = mtod(m, struct bwi_rxbuf_hdr *); flags2 = le16toh(hdr->rxh_flags2); hdr_extra = 0; if (flags2 & BWI_RXH_F2_TYPE2FRAME) hdr_extra = 2; wh_ofs = hdr_extra + 6; /* XXX magic number */ buflen = le16toh(hdr->rxh_buflen); if (buflen < BWI_FRAME_MIN_LEN(wh_ofs)) { aprint_error_dev(sc->sc_dev, "short frame %d," " hdr_extra %d\n", buflen, hdr_extra); ifp->if_ierrors++; m_freem(m); goto next; } plcp = ((const uint8_t *)(hdr + 1) + hdr_extra); rssi = bwi_calc_rssi(sc, hdr); m_set_rcvif(m, ifp); m->m_len = m->m_pkthdr.len = buflen + sizeof(*hdr); m_adj(m, sizeof(*hdr) + wh_ofs); if (htole16(hdr->rxh_flags1) & BWI_RXH_F1_OFDM) rate = bwi_ofdm_plcp2rate(plcp); else rate = bwi_ds_plcp2rate(plcp); s = splnet(); /* RX radio tap */ if (sc->sc_drvbpf != NULL) { struct mbuf mb; struct bwi_rx_radiotap_hdr *tap = &sc->sc_rxtap; tap->wr_tsf = hdr->rxh_tsf; tap->wr_flags = 0; tap->wr_rate = rate; tap->wr_chan_freq = htole16(ic->ic_bss->ni_chan->ic_freq); tap->wr_chan_flags = htole16(ic->ic_bss->ni_chan->ic_flags); tap->wr_antsignal = rssi; tap->wr_antnoise = BWI_NOISE_FLOOR; mb.m_data = (void *)tap; mb.m_len = sc->sc_rxtap_len; mb.m_next = m; mb.m_nextpkt = NULL; mb.m_type = 0; mb.m_flags = 0; bpf_mtap3(sc->sc_drvbpf, &mb); } m_adj(m, -IEEE80211_CRC_LEN); wh = mtod(m, struct ieee80211_frame_min *); ni = ieee80211_find_rxnode(ic, wh); type = wh->i_fc[0] & IEEE80211_FC0_TYPE_MASK; ieee80211_input(ic, m, ni, hdr->rxh_rssi, le16toh(hdr->rxh_tsf)); ieee80211_free_node(ni); if (type == IEEE80211_FC0_TYPE_DATA) { rx_data = 1; sc->sc_rx_rate = rate; } splx(s); next: idx = (idx + 1) % BWI_RX_NDESC; } rbd->rbd_idx = idx; bus_dmamap_sync(sc->sc_dmat, rd->rdata_dmap, 0, rd->rdata_dmap->dm_mapsize, BUS_DMASYNC_PREWRITE); return (rx_data); } static int bwi_rxeof32(struct bwi_softc *sc) { uint32_t val, rx_ctrl; int end_idx, rx_data; rx_ctrl = sc->sc_rx_rdata.rdata_txrx_ctrl; val = CSR_READ_4(sc, rx_ctrl + BWI_RX32_STATUS); end_idx = __SHIFTOUT(val, BWI_RX32_STATUS_INDEX_MASK) / sizeof(struct bwi_desc32); rx_data = bwi_rxeof(sc, end_idx); CSR_WRITE_4(sc, rx_ctrl + BWI_RX32_INDEX, end_idx * sizeof(struct bwi_desc32)); return (rx_data); } static int bwi_rxeof64(struct bwi_softc *sc) { /* TODO: 64 */ return (0); } static void bwi_reset_rx_ring32(struct bwi_softc *sc, uint32_t rx_ctrl) { int i; CSR_WRITE_4(sc, rx_ctrl + BWI_RX32_CTRL, 0); #define NRETRY 10 for (i = 0; i < NRETRY; ++i) { uint32_t status; status = CSR_READ_4(sc, rx_ctrl + BWI_RX32_STATUS); if (__SHIFTOUT(status, BWI_RX32_STATUS_STATE_MASK) == BWI_RX32_STATUS_STATE_DISABLED) break; DELAY(1000); } if (i == NRETRY) aprint_error_dev(sc->sc_dev, "reset rx ring timedout\n"); #undef NRETRY CSR_WRITE_4(sc, rx_ctrl + BWI_RX32_RINGINFO, 0); } static void bwi_free_txstats32(struct bwi_softc *sc) { bwi_reset_rx_ring32(sc, sc->sc_txstats->stats_ctrl_base); } static void bwi_free_rx_ring32(struct bwi_softc *sc) { struct bwi_ring_data *rd = &sc->sc_rx_rdata; struct bwi_rxbuf_data *rbd = &sc->sc_rx_bdata; int i; bwi_reset_rx_ring32(sc, rd->rdata_txrx_ctrl); for (i = 0; i < BWI_RX_NDESC; ++i) { struct bwi_rxbuf *rb = &rbd->rbd_buf[i]; if (rb->rb_mbuf != NULL) { bus_dmamap_unload(sc->sc_dmat, rb->rb_dmap); m_freem(rb->rb_mbuf); rb->rb_mbuf = NULL; } } } static void bwi_free_tx_ring32(struct bwi_softc *sc, int ring_idx) { struct bwi_ring_data *rd; struct bwi_txbuf_data *tbd; uint32_t state, val; int i; KASSERT(ring_idx < BWI_TX_NRING); rd = &sc->sc_tx_rdata[ring_idx]; tbd = &sc->sc_tx_bdata[ring_idx]; #define NRETRY 10 for (i = 0; i < NRETRY; ++i) { val = CSR_READ_4(sc, rd->rdata_txrx_ctrl + BWI_TX32_STATUS); state = __SHIFTOUT(val, BWI_TX32_STATUS_STATE_MASK); if (state == BWI_TX32_STATUS_STATE_DISABLED || state == BWI_TX32_STATUS_STATE_IDLE || state == BWI_TX32_STATUS_STATE_STOPPED) break; DELAY(1000); } if (i == NRETRY) aprint_error_dev(sc->sc_dev, "wait for TX ring(%d) stable timed out\n", ring_idx); CSR_WRITE_4(sc, rd->rdata_txrx_ctrl + BWI_TX32_CTRL, 0); for (i = 0; i < NRETRY; ++i) { val = CSR_READ_4(sc, rd->rdata_txrx_ctrl + BWI_TX32_STATUS); state = __SHIFTOUT(val, BWI_TX32_STATUS_STATE_MASK); if (state == BWI_TX32_STATUS_STATE_DISABLED) break; DELAY(1000); } if (i == NRETRY) aprint_error_dev(sc->sc_dev, "reset TX ring (%d) timed out\n", ring_idx); #undef NRETRY DELAY(1000); CSR_WRITE_4(sc, rd->rdata_txrx_ctrl + BWI_TX32_RINGINFO, 0); for (i = 0; i < BWI_TX_NDESC; ++i) { struct bwi_txbuf *tb = &tbd->tbd_buf[i]; if (tb->tb_mbuf != NULL) { bus_dmamap_unload(sc->sc_dmat, tb->tb_dmap); m_freem(tb->tb_mbuf); tb->tb_mbuf = NULL; } if (tb->tb_ni != NULL) { ieee80211_free_node(tb->tb_ni); tb->tb_ni = NULL; } } } static void bwi_free_txstats64(struct bwi_softc *sc) { /* TODO: 64 */ } static void bwi_free_rx_ring64(struct bwi_softc *sc) { /* TODO: 64 */ } static void bwi_free_tx_ring64(struct bwi_softc *sc, int ring_idx) { /* TODO: 64 */ } /* XXX does not belong here */ /* [TRC: Begin pilferage from OpenBSD.] */ /* * Convert bit rate (in 0.5Mbps units) to PLCP signal (R4-R1) and vice versa. */ uint8_t bwi_ieee80211_rate2plcp(u_int8_t rate, enum ieee80211_phymode mode) { rate &= IEEE80211_RATE_VAL; if (mode == IEEE80211_MODE_11B) { /* IEEE Std 802.11b-1999 page 15, subclause 18.2.3.3 */ switch (rate) { case 2: return 10; case 4: return 20; case 11: return 55; case 22: return 110; /* IEEE Std 802.11g-2003 page 19, subclause 19.3.2.1 */ case 44: return 220; } } else if (mode == IEEE80211_MODE_11G || mode == IEEE80211_MODE_11A) { /* IEEE Std 802.11a-1999 page 14, subclause 17.3.4.1 */ switch (rate) { case 12: return 0x0b; case 18: return 0x0f; case 24: return 0x0a; case 36: return 0x0e; case 48: return 0x09; case 72: return 0x0d; case 96: return 0x08; case 108: return 0x0c; } } else panic("Unexpected mode %u", mode); return 0; } static uint8_t bwi_ieee80211_plcp2rate(uint8_t plcp, enum ieee80211_phymode mode) { if (mode == IEEE80211_MODE_11B) { /* IEEE Std 802.11g-2003 page 19, subclause 19.3.2.1 */ switch (plcp) { case 10: return 2; case 20: return 4; case 55: return 11; case 110: return 22; /* IEEE Std 802.11g-2003 page 19, subclause 19.3.2.1 */ case 220: return 44; } } else if (mode == IEEE80211_MODE_11G || mode == IEEE80211_MODE_11A) { /* IEEE Std 802.11a-1999 page 14, subclause 17.3.4.1 */ switch (plcp) { case 0x0b: return 12; case 0x0f: return 18; case 0x0a: return 24; case 0x0e: return 36; case 0x09: return 48; case 0x0d: return 72; case 0x08: return 96; case 0x0c: return 108; } } else panic("Unexpected mode %u", mode); return 0; } /* [TRC: End pilferage from OpenBSD.] */ static enum bwi_ieee80211_modtype bwi_ieee80211_rate2modtype(uint8_t rate) { rate &= IEEE80211_RATE_VAL; if (rate == 44) return (IEEE80211_MODTYPE_PBCC); else if (rate == 22 || rate < 12) return (IEEE80211_MODTYPE_DS); else return (IEEE80211_MODTYPE_OFDM); } static uint8_t bwi_ofdm_plcp2rate(const void *plcp0) { uint32_t plcp; uint8_t plcp_rate; /* plcp0 may not be 32-bit aligned. */ plcp = le32dec(plcp0); plcp_rate = __SHIFTOUT(plcp, IEEE80211_OFDM_PLCP_RATE_MASK); return (bwi_ieee80211_plcp2rate(plcp_rate, IEEE80211_MODE_11G)); } static uint8_t bwi_ds_plcp2rate(const struct ieee80211_ds_plcp_hdr *hdr) { return (bwi_ieee80211_plcp2rate(hdr->i_signal, IEEE80211_MODE_11B)); } static void bwi_ofdm_plcp_header(uint32_t *plcp0, int pkt_len, uint8_t rate) { uint32_t plcp; plcp = __SHIFTIN(bwi_ieee80211_rate2plcp(rate, IEEE80211_MODE_11G), IEEE80211_OFDM_PLCP_RATE_MASK) | __SHIFTIN(pkt_len, IEEE80211_OFDM_PLCP_LEN_MASK); *plcp0 = htole32(plcp); } static void bwi_ds_plcp_header(struct ieee80211_ds_plcp_hdr *plcp, int pkt_len, uint8_t rate) { int len, service, pkt_bitlen; pkt_bitlen = pkt_len * NBBY; len = howmany(pkt_bitlen * 2, rate); service = IEEE80211_DS_PLCP_SERVICE_LOCKED; if (rate == (11 * 2)) { int pkt_bitlen1; /* * PLCP service field needs to be adjusted, * if TX rate is 11Mbytes/s */ pkt_bitlen1 = len * 11; if (pkt_bitlen1 - pkt_bitlen >= NBBY) service |= IEEE80211_DS_PLCP_SERVICE_LENEXT7; } plcp->i_signal = bwi_ieee80211_rate2plcp(rate, IEEE80211_MODE_11B); plcp->i_service = service; plcp->i_length = htole16(len); /* NOTE: do NOT touch i_crc */ } static void bwi_plcp_header(void *plcp, int pkt_len, uint8_t rate) { enum bwi_ieee80211_modtype modtype; /* * Assume caller has zeroed 'plcp' */ modtype = bwi_ieee80211_rate2modtype(rate); if (modtype == IEEE80211_MODTYPE_OFDM) bwi_ofdm_plcp_header(plcp, pkt_len, rate); else if (modtype == IEEE80211_MODTYPE_DS) bwi_ds_plcp_header(plcp, pkt_len, rate); else panic("unsupport modulation type %u\n", modtype); } static uint8_t bwi_ieee80211_ack_rate(struct ieee80211_node *ni, uint8_t rate) { const struct ieee80211_rateset *rs = &ni->ni_rates; uint8_t ack_rate = 0; enum bwi_ieee80211_modtype modtype; int i; rate &= IEEE80211_RATE_VAL; modtype = bwi_ieee80211_rate2modtype(rate); for (i = 0; i < rs->rs_nrates; ++i) { uint8_t rate1 = rs->rs_rates[i] & IEEE80211_RATE_VAL; if (rate1 > rate) { if (ack_rate != 0) return (ack_rate); else break; } if ((rs->rs_rates[i] & IEEE80211_RATE_BASIC) && bwi_ieee80211_rate2modtype(rate1) == modtype) ack_rate = rate1; } switch (rate) { /* CCK */ case 2: case 4: case 11: case 22: ack_rate = rate; break; /* PBCC */ case 44: ack_rate = 22; break; /* OFDM */ case 12: case 18: ack_rate = 12; break; case 24: case 36: ack_rate = 24; break; case 48: case 72: case 96: case 108: ack_rate = 48; break; default: panic("unsupported rate %d\n", rate); } return (ack_rate); } /* [TRC: XXX does not belong here] */ #define IEEE80211_OFDM_TXTIME(kbps, frmlen) \ (IEEE80211_OFDM_PREAMBLE_TIME + \ IEEE80211_OFDM_SIGNAL_TIME + \ (IEEE80211_OFDM_NSYMS((kbps), (frmlen)) * IEEE80211_OFDM_SYM_TIME)) #define IEEE80211_OFDM_SYM_TIME 4 #define IEEE80211_OFDM_PREAMBLE_TIME 16 #define IEEE80211_OFDM_SIGNAL_EXT_TIME 6 #define IEEE80211_OFDM_SIGNAL_TIME 4 #define IEEE80211_OFDM_PLCP_SERVICE_NBITS 16 #define IEEE80211_OFDM_TAIL_NBITS 6 #define IEEE80211_OFDM_NBITS(frmlen) \ (IEEE80211_OFDM_PLCP_SERVICE_NBITS + \ ((frmlen) * NBBY) + \ IEEE80211_OFDM_TAIL_NBITS) #define IEEE80211_OFDM_NBITS_PER_SYM(kbps) \ (((kbps) * IEEE80211_OFDM_SYM_TIME) / 1000) #define IEEE80211_OFDM_NSYMS(kbps, frmlen) \ howmany(IEEE80211_OFDM_NBITS((frmlen)), \ IEEE80211_OFDM_NBITS_PER_SYM((kbps))) #define IEEE80211_CCK_TXTIME(kbps, frmlen) \ (((IEEE80211_CCK_NBITS((frmlen)) * 1000) + (kbps) - 1) / (kbps)) #define IEEE80211_CCK_PREAMBLE_LEN 144 #define IEEE80211_CCK_PLCP_HDR_TIME 48 #define IEEE80211_CCK_SHPREAMBLE_LEN 72 #define IEEE80211_CCK_SHPLCP_HDR_TIME 24 #define IEEE80211_CCK_NBITS(frmlen) ((frmlen) * NBBY) static uint16_t bwi_ieee80211_txtime(struct ieee80211com *ic, struct ieee80211_node *ni, uint len, uint8_t rs_rate, uint32_t flags) { enum bwi_ieee80211_modtype modtype; uint16_t txtime; int rate; rs_rate &= IEEE80211_RATE_VAL; rate = rs_rate * 500; /* ieee80211 rate -> kbps */ modtype = bwi_ieee80211_rate2modtype(rs_rate); if (modtype == IEEE80211_MODTYPE_OFDM) { /* * IEEE Std 802.11a-1999, page 37, equation (29) * IEEE Std 802.11g-2003, page 44, equation (42) */ txtime = IEEE80211_OFDM_TXTIME(rate, len); if (ic->ic_curmode == IEEE80211_MODE_11G) txtime += IEEE80211_OFDM_SIGNAL_EXT_TIME; } else { /* * IEEE Std 802.11b-1999, page 28, subclause 18.3.4 * IEEE Std 802.11g-2003, page 45, equation (43) */ if (modtype == IEEE80211_MODTYPE_PBCC) ++len; txtime = IEEE80211_CCK_TXTIME(rate, len); /* * Short preamble is not applicable for DS 1Mbits/s */ if (rs_rate != 2 && (flags & IEEE80211_F_SHPREAMBLE)) { txtime += IEEE80211_CCK_SHPREAMBLE_LEN + IEEE80211_CCK_SHPLCP_HDR_TIME; } else { txtime += IEEE80211_CCK_PREAMBLE_LEN + IEEE80211_CCK_PLCP_HDR_TIME; } } return (txtime); } static int bwi_encap(struct bwi_softc *sc, int idx, struct mbuf *m, struct ieee80211_node **nip, int mgt_pkt) { struct ieee80211com *ic = &sc->sc_ic; struct ieee80211_node *ni = *nip; struct bwi_ring_data *rd = &sc->sc_tx_rdata[BWI_TX_DATA_RING]; struct bwi_txbuf_data *tbd = &sc->sc_tx_bdata[BWI_TX_DATA_RING]; struct bwi_txbuf *tb = &tbd->tbd_buf[idx]; struct bwi_mac *mac; struct bwi_txbuf_hdr *hdr; struct ieee80211_frame *wh; uint8_t rate; /* [TRC: XXX Use a fallback rate?] */ uint32_t mac_ctrl; uint16_t phy_ctrl; bus_addr_t paddr; int pkt_len, error, mcast_pkt = 0; #if 0 const uint8_t *p; int i; #endif KASSERT(ni != NULL); KASSERT(sc->sc_cur_regwin->rw_type == BWI_REGWIN_T_MAC); mac = (struct bwi_mac *)sc->sc_cur_regwin; wh = mtod(m, struct ieee80211_frame *); /* Get 802.11 frame len before prepending TX header */ pkt_len = m->m_pkthdr.len + IEEE80211_CRC_LEN; /* * Find TX rate */ memset(tb->tb_rate_idx, 0, sizeof(tb->tb_rate_idx)); if (!mgt_pkt) { if (ic->ic_fixed_rate != -1) { rate = ic->ic_sup_rates[ic->ic_curmode]. rs_rates[ic->ic_fixed_rate]; /* [TRC: XXX Set fallback rate.] */ } else { /* AMRR rate control */ /* [TRC: XXX amrr] */ /* rate = ni->ni_rates.rs_rates[ni->ni_txrate]; */ rate = (1 * 2); /* [TRC: XXX Set fallback rate.] */ } } else { /* Fixed at 1Mbits/s for mgt frames */ /* [TRC: XXX Set fallback rate.] */ rate = (1 * 2); } rate &= IEEE80211_RATE_VAL; if (IEEE80211_IS_MULTICAST(wh->i_addr1)) { /* [TRC: XXX Set fallback rate.] */ rate = ic->ic_mcast_rate; mcast_pkt = 1; } /* [TRC: XXX Check fallback rate.] */ if (rate == 0) { aprint_error_dev(sc->sc_dev, "invalid rate %u", rate); /* [TRC: In the margin of the following line, DragonFlyBSD writes `Force 1Mbits/s', whereas OpenBSD writes `Force 1Mbytes/s'.] */ rate = (1 * 2); /* [TRC: XXX Set fallback rate.] */ } sc->sc_tx_rate = rate; /* TX radio tap */ if (sc->sc_drvbpf != NULL) { struct mbuf mb; struct bwi_tx_radiotap_hdr *tap = &sc->sc_txtap; tap->wt_flags = 0; tap->wt_rate = rate; tap->wt_chan_freq = htole16(ic->ic_bss->ni_chan->ic_freq); tap->wt_chan_flags = htole16(ic->ic_bss->ni_chan->ic_flags); mb.m_data = (void *)tap; mb.m_len = sc->sc_txtap_len; mb.m_next = m; mb.m_nextpkt = NULL; mb.m_type = 0; mb.m_flags = 0; bpf_mtap3(sc->sc_drvbpf, &mb); } /* * Setup the embedded TX header */ M_PREPEND(m, sizeof(*hdr), M_DONTWAIT); if (m == NULL) { aprint_error_dev(sc->sc_dev, "prepend TX header failed\n"); return (ENOBUFS); } hdr = mtod(m, struct bwi_txbuf_hdr *); memset(hdr, 0, sizeof(*hdr)); memcpy(hdr->txh_fc, wh->i_fc, sizeof(hdr->txh_fc)); memcpy(hdr->txh_addr1, wh->i_addr1, sizeof(hdr->txh_addr1)); if (!mcast_pkt) { uint16_t dur; uint8_t ack_rate; /* [TRC: XXX Set fallback rate.] */ ack_rate = bwi_ieee80211_ack_rate(ni, rate); dur = bwi_ieee80211_txtime(ic, ni, sizeof(struct ieee80211_frame_ack) + IEEE80211_CRC_LEN, ack_rate, ic->ic_flags & IEEE80211_F_SHPREAMBLE); hdr->txh_fb_duration = htole16(dur); } hdr->txh_id = htole16( __SHIFTIN(BWI_TX_DATA_RING, BWI_TXH_ID_RING_MASK) | __SHIFTIN(idx, BWI_TXH_ID_IDX_MASK)); bwi_plcp_header(hdr->txh_plcp, pkt_len, rate); /* [TRC: XXX Use fallback rate.] */ bwi_plcp_header(hdr->txh_fb_plcp, pkt_len, rate); phy_ctrl = __SHIFTIN(mac->mac_rf.rf_ant_mode, BWI_TXH_PHY_C_ANTMODE_MASK); if (bwi_ieee80211_rate2modtype(rate) == IEEE80211_MODTYPE_OFDM) phy_ctrl |= BWI_TXH_PHY_C_OFDM; else if ((ic->ic_flags & IEEE80211_F_SHPREAMBLE) && rate != (2 * 1)) phy_ctrl |= BWI_TXH_PHY_C_SHPREAMBLE; mac_ctrl = BWI_TXH_MAC_C_HWSEQ | BWI_TXH_MAC_C_FIRST_FRAG; if (!IEEE80211_IS_MULTICAST(wh->i_addr1)) mac_ctrl |= BWI_TXH_MAC_C_ACK; if (bwi_ieee80211_rate2modtype(rate) == IEEE80211_MODTYPE_OFDM) mac_ctrl |= BWI_TXH_MAC_C_FB_OFDM; hdr->txh_mac_ctrl = htole32(mac_ctrl); hdr->txh_phy_ctrl = htole16(phy_ctrl); /* Catch any further usage */ hdr = NULL; wh = NULL; /* DMA load */ error = bus_dmamap_load_mbuf(sc->sc_dmat, tb->tb_dmap, m, BUS_DMA_NOWAIT); if (error && error != EFBIG) { aprint_error_dev(sc->sc_dev, "can't load TX buffer (1) %d\n", error); goto back; } if (error) { /* error == EFBIG */ struct mbuf *m_new; error = 0; MGETHDR(m_new, M_DONTWAIT, MT_DATA); if (m_new == NULL) { error = ENOBUFS; aprint_error_dev(sc->sc_dev, "can't defrag TX buffer (1)\n"); goto back; } M_COPY_PKTHDR(m_new, m); if (m->m_pkthdr.len > MHLEN) { MCLGET(m_new, M_DONTWAIT); if (!(m_new->m_flags & M_EXT)) { m_freem(m_new); error = ENOBUFS; } } if (error) { aprint_error_dev(sc->sc_dev, "can't defrag TX buffer (2)\n"); goto back; } m_copydata(m, 0, m->m_pkthdr.len, mtod(m_new, void *)); m_freem(m); m_new->m_len = m_new->m_pkthdr.len; m = m_new; error = bus_dmamap_load_mbuf(sc->sc_dmat, tb->tb_dmap, m, BUS_DMA_NOWAIT); if (error) { aprint_error_dev(sc->sc_dev, "can't load TX buffer (2) %d\n", error); goto back; } } error = 0; bus_dmamap_sync(sc->sc_dmat, tb->tb_dmap, 0, tb->tb_dmap->dm_mapsize, BUS_DMASYNC_PREWRITE); if (mgt_pkt || mcast_pkt) { /* Don't involve mcast/mgt packets into TX rate control */ ieee80211_free_node(ni); *nip = ni = NULL; } tb->tb_mbuf = m; tb->tb_ni = ni; #if 0 p = mtod(m, const uint8_t *); for (i = 0; i < m->m_pkthdr.len; ++i) { if (i % 8 == 0) { if (i != 0) aprint_debug("\n"); aprint_debug_dev(sc->sc_dev, ""); } aprint_debug(" %02x", p[i]); } aprint_debug("\n"); #endif DPRINTF(sc, BWI_DBG_TX, "idx %d, pkt_len %d, buflen %d\n", idx, pkt_len, m->m_pkthdr.len); /* Setup TX descriptor */ paddr = tb->tb_dmap->dm_segs[0].ds_addr; (sc->sc_setup_txdesc)(sc, rd, idx, paddr, m->m_pkthdr.len); bus_dmamap_sync(sc->sc_dmat, rd->rdata_dmap, 0, rd->rdata_dmap->dm_mapsize, BUS_DMASYNC_PREWRITE); /* Kick start */ (sc->sc_start_tx)(sc, rd->rdata_txrx_ctrl, idx); back: if (error) m_freem(m); return (error); } static void bwi_start_tx32(struct bwi_softc *sc, uint32_t tx_ctrl, int idx) { idx = (idx + 1) % BWI_TX_NDESC; CSR_WRITE_4(sc, tx_ctrl + BWI_TX32_INDEX, idx * sizeof(struct bwi_desc32)); } static void bwi_start_tx64(struct bwi_softc *sc, uint32_t tx_ctrl, int idx) { /* TODO: 64 */ } static void bwi_txeof_status32(struct bwi_softc *sc) { struct ifnet *ifp = &sc->sc_if; uint32_t val, ctrl_base; int end_idx, s; s = splnet(); ctrl_base = sc->sc_txstats->stats_ctrl_base; val = CSR_READ_4(sc, ctrl_base + BWI_RX32_STATUS); end_idx = __SHIFTOUT(val, BWI_RX32_STATUS_INDEX_MASK) / sizeof(struct bwi_desc32); bwi_txeof_status(sc, end_idx); CSR_WRITE_4(sc, ctrl_base + BWI_RX32_INDEX, end_idx * sizeof(struct bwi_desc32)); if ((ifp->if_flags & IFF_OACTIVE) == 0) ifp->if_start(ifp); /* [TRC: XXX Why not bwi_start?] */ splx(s); } static void bwi_txeof_status64(struct bwi_softc *sc) { /* TODO: 64 */ } static void _bwi_txeof(struct bwi_softc *sc, uint16_t tx_id) { struct ifnet *ifp = &sc->sc_if; struct bwi_txbuf_data *tbd; struct bwi_txbuf *tb; int ring_idx, buf_idx; if (tx_id == 0) { /* [TRC: XXX What is the severity of this message?] */ aprint_normal_dev(sc->sc_dev, "zero tx id\n"); return; } ring_idx = __SHIFTOUT(tx_id, BWI_TXH_ID_RING_MASK); buf_idx = __SHIFTOUT(tx_id, BWI_TXH_ID_IDX_MASK); KASSERT(ring_idx == BWI_TX_DATA_RING); KASSERT(buf_idx < BWI_TX_NDESC); tbd = &sc->sc_tx_bdata[ring_idx]; KASSERT(tbd->tbd_used > 0); tbd->tbd_used--; tb = &tbd->tbd_buf[buf_idx]; bus_dmamap_unload(sc->sc_dmat, tb->tb_dmap); m_freem(tb->tb_mbuf); tb->tb_mbuf = NULL; if (tb->tb_ni != NULL) { ieee80211_free_node(tb->tb_ni); tb->tb_ni = NULL; } if (tbd->tbd_used == 0) sc->sc_tx_timer = 0; ifp->if_flags &= ~IFF_OACTIVE; } static void bwi_txeof_status(struct bwi_softc *sc, int end_idx) { struct bwi_txstats_data *st = sc->sc_txstats; int idx; bus_dmamap_sync(sc->sc_dmat, st->stats_dmap, 0, st->stats_dmap->dm_mapsize, BUS_DMASYNC_POSTREAD); idx = st->stats_idx; while (idx != end_idx) { /* [TRC: XXX Filter this out if it is not pending; see DragonFlyBSD's revision 1.5. */ _bwi_txeof(sc, le16toh(st->stats[idx].txs_id)); idx = (idx + 1) % BWI_TXSTATS_NDESC; } st->stats_idx = idx; } static void bwi_txeof(struct bwi_softc *sc) { struct ifnet *ifp = &sc->sc_if; int s; s = splnet(); for (;;) { uint32_t tx_status0; uint16_t tx_id, tx_info; tx_status0 = CSR_READ_4(sc, BWI_TXSTATUS_0); if ((tx_status0 & BWI_TXSTATUS_0_MORE) == 0) break; (void)CSR_READ_4(sc, BWI_TXSTATUS_1); tx_id = __SHIFTOUT(tx_status0, BWI_TXSTATUS_0_TXID_MASK); tx_info = BWI_TXSTATUS_0_INFO(tx_status0); if (tx_info & 0x30) /* XXX */ continue; _bwi_txeof(sc, tx_id); ifp->if_opackets++; } if ((ifp->if_flags & IFF_OACTIVE) == 0) ifp->if_start(ifp); splx(s); } static int bwi_bbp_power_on(struct bwi_softc *sc, enum bwi_clock_mode clk_mode) { bwi_power_on(sc, 1); return (bwi_set_clock_mode(sc, clk_mode)); } static void bwi_bbp_power_off(struct bwi_softc *sc) { bwi_set_clock_mode(sc, BWI_CLOCK_MODE_SLOW); bwi_power_off(sc, 1); } static int bwi_get_pwron_delay(struct bwi_softc *sc) { struct bwi_regwin *com, *old; struct bwi_clock_freq freq; uint32_t val; int error; com = &sc->sc_com_regwin; KASSERT(BWI_REGWIN_EXIST(com)); if ((sc->sc_cap & BWI_CAP_CLKMODE) == 0) return (0); error = bwi_regwin_switch(sc, com, &old); if (error) return (error); bwi_get_clock_freq(sc, &freq); val = CSR_READ_4(sc, BWI_PLL_ON_DELAY); sc->sc_pwron_delay = howmany((val + 2) * 1000000, freq.clkfreq_min); DPRINTF(sc, BWI_DBG_ATTACH, "power on delay %u\n", sc->sc_pwron_delay); return (bwi_regwin_switch(sc, old, NULL)); } static int bwi_bus_attach(struct bwi_softc *sc) { struct bwi_regwin *bus, *old; int error; bus = &sc->sc_bus_regwin; error = bwi_regwin_switch(sc, bus, &old); if (error) return (error); if (!bwi_regwin_is_enabled(sc, bus)) bwi_regwin_enable(sc, bus, 0); /* Disable interripts */ CSR_WRITE_4(sc, BWI_INTRVEC, 0); return (bwi_regwin_switch(sc, old, NULL)); } static const char * bwi_regwin_name(const struct bwi_regwin *rw) { switch (rw->rw_type) { case BWI_REGWIN_T_COM: return ("COM"); case BWI_REGWIN_T_BUSPCI: return ("PCI"); case BWI_REGWIN_T_MAC: return ("MAC"); case BWI_REGWIN_T_BUSPCIE: return ("PCIE"); } panic("unknown regwin type 0x%04x\n", rw->rw_type); return (NULL); } static uint32_t bwi_regwin_disable_bits(struct bwi_softc *sc) { uint32_t busrev; /* XXX cache this */ busrev = __SHIFTOUT(CSR_READ_4(sc, BWI_ID_LO), BWI_ID_LO_BUSREV_MASK); DPRINTF(sc, BWI_DBG_ATTACH | BWI_DBG_INIT | BWI_DBG_MISC, "bus rev %u\n", busrev); if (busrev == BWI_BUSREV_0) return (BWI_STATE_LO_DISABLE1); else if (busrev == BWI_BUSREV_1) return (BWI_STATE_LO_DISABLE2); else return (BWI_STATE_LO_DISABLE1 | BWI_STATE_LO_DISABLE2); } static int bwi_regwin_is_enabled(struct bwi_softc *sc, struct bwi_regwin *rw) { uint32_t val, disable_bits; disable_bits = bwi_regwin_disable_bits(sc); val = CSR_READ_4(sc, BWI_STATE_LO); if ((val & (BWI_STATE_LO_CLOCK | BWI_STATE_LO_RESET | disable_bits)) == BWI_STATE_LO_CLOCK) { DPRINTF(sc, BWI_DBG_ATTACH | BWI_DBG_INIT, "%s is enabled\n", bwi_regwin_name(rw)); return (1); } else { DPRINTF(sc, BWI_DBG_ATTACH | BWI_DBG_INIT, "%s is disabled\n", bwi_regwin_name(rw)); return (0); } } static void bwi_regwin_disable(struct bwi_softc *sc, struct bwi_regwin *rw, uint32_t flags) { uint32_t state_lo, disable_bits; int i; state_lo = CSR_READ_4(sc, BWI_STATE_LO); /* * If current regwin is in 'reset' state, it was already disabled. */ if (state_lo & BWI_STATE_LO_RESET) { DPRINTF(sc, BWI_DBG_ATTACH | BWI_DBG_INIT, "%s was already disabled\n", bwi_regwin_name(rw)); return; } disable_bits = bwi_regwin_disable_bits(sc); /* * Disable normal clock */ state_lo = BWI_STATE_LO_CLOCK | disable_bits; CSR_WRITE_4(sc, BWI_STATE_LO, state_lo); /* * Wait until normal clock is disabled */ #define NRETRY 1000 for (i = 0; i < NRETRY; ++i) { state_lo = CSR_READ_4(sc, BWI_STATE_LO); if (state_lo & disable_bits) break; DELAY(10); } if (i == NRETRY) { aprint_error_dev(sc->sc_dev, "%s disable clock timeout\n", bwi_regwin_name(rw)); } for (i = 0; i < NRETRY; ++i) { uint32_t state_hi; state_hi = CSR_READ_4(sc, BWI_STATE_HI); if ((state_hi & BWI_STATE_HI_BUSY) == 0) break; DELAY(10); } if (i == NRETRY) { aprint_error_dev(sc->sc_dev, "%s wait BUSY unset timeout\n", bwi_regwin_name(rw)); } #undef NRETRY /* * Reset and disable regwin with gated clock */ state_lo = BWI_STATE_LO_RESET | disable_bits | BWI_STATE_LO_CLOCK | BWI_STATE_LO_GATED_CLOCK | __SHIFTIN(flags, BWI_STATE_LO_FLAGS_MASK); CSR_WRITE_4(sc, BWI_STATE_LO, state_lo); /* Flush pending bus write */ CSR_READ_4(sc, BWI_STATE_LO); DELAY(1); /* Reset and disable regwin */ state_lo = BWI_STATE_LO_RESET | disable_bits | __SHIFTIN(flags, BWI_STATE_LO_FLAGS_MASK); CSR_WRITE_4(sc, BWI_STATE_LO, state_lo); /* Flush pending bus write */ CSR_READ_4(sc, BWI_STATE_LO); DELAY(1); } static void bwi_regwin_enable(struct bwi_softc *sc, struct bwi_regwin *rw, uint32_t flags) { uint32_t state_lo, state_hi, imstate; bwi_regwin_disable(sc, rw, flags); /* Reset regwin with gated clock */ state_lo = BWI_STATE_LO_RESET | BWI_STATE_LO_CLOCK | BWI_STATE_LO_GATED_CLOCK | __SHIFTIN(flags, BWI_STATE_LO_FLAGS_MASK); CSR_WRITE_4(sc, BWI_STATE_LO, state_lo); /* Flush pending bus write */ CSR_READ_4(sc, BWI_STATE_LO); DELAY(1); state_hi = CSR_READ_4(sc, BWI_STATE_HI); if (state_hi & BWI_STATE_HI_SERROR) CSR_WRITE_4(sc, BWI_STATE_HI, 0); imstate = CSR_READ_4(sc, BWI_IMSTATE); if (imstate & (BWI_IMSTATE_INBAND_ERR | BWI_IMSTATE_TIMEOUT)) { imstate &= ~(BWI_IMSTATE_INBAND_ERR | BWI_IMSTATE_TIMEOUT); CSR_WRITE_4(sc, BWI_IMSTATE, imstate); } /* Enable regwin with gated clock */ state_lo = BWI_STATE_LO_CLOCK | BWI_STATE_LO_GATED_CLOCK | __SHIFTIN(flags, BWI_STATE_LO_FLAGS_MASK); CSR_WRITE_4(sc, BWI_STATE_LO, state_lo); /* Flush pending bus write */ CSR_READ_4(sc, BWI_STATE_LO); DELAY(1); /* Enable regwin with normal clock */ state_lo = BWI_STATE_LO_CLOCK | __SHIFTIN(flags, BWI_STATE_LO_FLAGS_MASK); CSR_WRITE_4(sc, BWI_STATE_LO, state_lo); /* Flush pending bus write */ CSR_READ_4(sc, BWI_STATE_LO); DELAY(1); } static void bwi_set_bssid(struct bwi_softc *sc, const uint8_t *bssid) { struct ieee80211com *ic = &sc->sc_ic; struct bwi_mac *mac; struct bwi_myaddr_bssid buf; const uint8_t *p; uint32_t val; int n, i; KASSERT(sc->sc_cur_regwin->rw_type == BWI_REGWIN_T_MAC); mac = (struct bwi_mac *)sc->sc_cur_regwin; bwi_set_addr_filter(sc, BWI_ADDR_FILTER_BSSID, bssid); memcpy(buf.myaddr, ic->ic_myaddr, sizeof(buf.myaddr)); memcpy(buf.bssid, bssid, sizeof(buf.bssid)); n = sizeof(buf) / sizeof(val); p = (const uint8_t *)&buf; for (i = 0; i < n; ++i) { int j; val = 0; for (j = 0; j < sizeof(val); ++j) val |= ((uint32_t)(*p++)) << (j * 8); TMPLT_WRITE_4(mac, 0x20 + (i * sizeof(val)), val); } } static void bwi_updateslot(struct ifnet *ifp) { struct bwi_softc *sc = ifp->if_softc; struct ieee80211com *ic = &sc->sc_ic; struct bwi_mac *mac; if ((ifp->if_flags & IFF_RUNNING) == 0) return; DPRINTF(sc, BWI_DBG_80211, "%s\n", __func__); KASSERT(sc->sc_cur_regwin->rw_type == BWI_REGWIN_T_MAC); mac = (struct bwi_mac *)sc->sc_cur_regwin; bwi_mac_updateslot(mac, (ic->ic_flags & IEEE80211_F_SHSLOT)); } static void bwi_calibrate(void *xsc) { struct bwi_softc *sc = xsc; struct ieee80211com *ic = &sc->sc_ic; int s; s = splnet(); if (ic->ic_state == IEEE80211_S_RUN) { struct bwi_mac *mac; KASSERT(sc->sc_cur_regwin->rw_type == BWI_REGWIN_T_MAC); mac = (struct bwi_mac *)sc->sc_cur_regwin; if (ic->ic_opmode != IEEE80211_M_MONITOR) { bwi_mac_calibrate_txpower(mac, sc->sc_txpwrcb_type); sc->sc_txpwrcb_type = BWI_TXPWR_CALIB; } /* XXX 15 seconds */ callout_schedule(&sc->sc_calib_ch, hz * 15); } splx(s); } static int bwi_calc_rssi(struct bwi_softc *sc, const struct bwi_rxbuf_hdr *hdr) { struct bwi_mac *mac; KASSERT(sc->sc_cur_regwin->rw_type == BWI_REGWIN_T_MAC); mac = (struct bwi_mac *)sc->sc_cur_regwin; return (bwi_rf_calc_rssi(mac, hdr)); } bool bwi_suspend(device_t dv, const pmf_qual_t *qual) { struct bwi_softc *sc = device_private(dv); bwi_power_off(sc, 0); if (sc->sc_disable != NULL) (sc->sc_disable)(sc, 1); return true; } bool bwi_resume(device_t dv, const pmf_qual_t *qual) { struct bwi_softc *sc = device_private(dv); if (sc->sc_enable != NULL) (sc->sc_enable)(sc, 1); bwi_power_on(sc, 1); return true; }