/* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* * Copyright (c) 2006 * Damien Bergamini * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * Driver for Intel PRO/Wireless 3945ABG 802.11 network adapters. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "wpireg.h" #include "wpivar.h" #include #ifdef DEBUG #define WPI_DEBUG_80211 (1 << 0) #define WPI_DEBUG_CMD (1 << 1) #define WPI_DEBUG_DMA (1 << 2) #define WPI_DEBUG_EEPROM (1 << 3) #define WPI_DEBUG_FW (1 << 4) #define WPI_DEBUG_HW (1 << 5) #define WPI_DEBUG_INTR (1 << 6) #define WPI_DEBUG_MRR (1 << 7) #define WPI_DEBUG_PIO (1 << 8) #define WPI_DEBUG_RX (1 << 9) #define WPI_DEBUG_SCAN (1 << 10) #define WPI_DEBUG_TX (1 << 11) #define WPI_DEBUG_RATECTL (1 << 12) #define WPI_DEBUG_RADIO (1 << 13) #define WPI_DEBUG_RESUME (1 << 14) uint32_t wpi_dbg_flags = 0; #define WPI_DBG(x) \ wpi_dbg x #else #define WPI_DBG(x) #endif static void *wpi_soft_state_p = NULL; static uint8_t wpi_fw_bin [] = { #include "fw-wpi/ipw3945.ucode.hex" }; /* DMA attributes for a shared page */ static ddi_dma_attr_t sh_dma_attr = { DMA_ATTR_V0, /* version of this structure */ 0, /* lowest usable address */ 0xffffffffU, /* highest usable address */ 0xffffffffU, /* maximum DMAable byte count */ 0x1000, /* alignment in bytes */ 0x1000, /* burst sizes (any?) */ 1, /* minimum transfer */ 0xffffffffU, /* maximum transfer */ 0xffffffffU, /* maximum segment length */ 1, /* maximum number of segments */ 1, /* granularity */ 0, /* flags (reserved) */ }; /* DMA attributes for a ring descriptor */ static ddi_dma_attr_t ring_desc_dma_attr = { DMA_ATTR_V0, /* version of this structure */ 0, /* lowest usable address */ 0xffffffffU, /* highest usable address */ 0xffffffffU, /* maximum DMAable byte count */ 0x4000, /* alignment in bytes */ 0x100, /* burst sizes (any?) */ 1, /* minimum transfer */ 0xffffffffU, /* maximum transfer */ 0xffffffffU, /* maximum segment length */ 1, /* maximum number of segments */ 1, /* granularity */ 0, /* flags (reserved) */ }; /* DMA attributes for a tx cmd */ static ddi_dma_attr_t tx_cmd_dma_attr = { DMA_ATTR_V0, /* version of this structure */ 0, /* lowest usable address */ 0xffffffffU, /* highest usable address */ 0xffffffffU, /* maximum DMAable byte count */ 4, /* alignment in bytes */ 0x100, /* burst sizes (any?) */ 1, /* minimum transfer */ 0xffffffffU, /* maximum transfer */ 0xffffffffU, /* maximum segment length */ 1, /* maximum number of segments */ 1, /* granularity */ 0, /* flags (reserved) */ }; /* DMA attributes for a rx buffer */ static ddi_dma_attr_t rx_buffer_dma_attr = { DMA_ATTR_V0, /* version of this structure */ 0, /* lowest usable address */ 0xffffffffU, /* highest usable address */ 0xffffffffU, /* maximum DMAable byte count */ 1, /* alignment in bytes */ 0x100, /* burst sizes (any?) */ 1, /* minimum transfer */ 0xffffffffU, /* maximum transfer */ 0xffffffffU, /* maximum segment length */ 1, /* maximum number of segments */ 1, /* granularity */ 0, /* flags (reserved) */ }; /* * DMA attributes for a tx buffer. * the maximum number of segments is 4 for the hardware. * now all the wifi drivers put the whole frame in a single * descriptor, so we define the maximum number of segments 4, * just the same as the rx_buffer. we consider leverage the HW * ability in the future, that is why we don't define rx and tx * buffer_dma_attr as the same. */ static ddi_dma_attr_t tx_buffer_dma_attr = { DMA_ATTR_V0, /* version of this structure */ 0, /* lowest usable address */ 0xffffffffU, /* highest usable address */ 0xffffffffU, /* maximum DMAable byte count */ 1, /* alignment in bytes */ 0x100, /* burst sizes (any?) */ 1, /* minimum transfer */ 0xffffffffU, /* maximum transfer */ 0xffffffffU, /* maximum segment length */ 1, /* maximum number of segments */ 1, /* granularity */ 0, /* flags (reserved) */ }; /* DMA attributes for a load firmware */ static ddi_dma_attr_t fw_buffer_dma_attr = { DMA_ATTR_V0, /* version of this structure */ 0, /* lowest usable address */ 0xffffffffU, /* highest usable address */ 0x7fffffff, /* maximum DMAable byte count */ 4, /* alignment in bytes */ 0x100, /* burst sizes (any?) */ 1, /* minimum transfer */ 0xffffffffU, /* maximum transfer */ 0xffffffffU, /* maximum segment length */ 4, /* maximum number of segments */ 1, /* granularity */ 0, /* flags (reserved) */ }; /* regs access attributes */ static ddi_device_acc_attr_t wpi_reg_accattr = { DDI_DEVICE_ATTR_V0, DDI_STRUCTURE_LE_ACC, DDI_STRICTORDER_ACC, DDI_DEFAULT_ACC }; /* DMA access attributes */ static ddi_device_acc_attr_t wpi_dma_accattr = { DDI_DEVICE_ATTR_V0, DDI_NEVERSWAP_ACC, DDI_STRICTORDER_ACC, DDI_DEFAULT_ACC }; static int wpi_ring_init(wpi_sc_t *); static void wpi_ring_free(wpi_sc_t *); static int wpi_alloc_shared(wpi_sc_t *); static void wpi_free_shared(wpi_sc_t *); static int wpi_alloc_fw_dma(wpi_sc_t *); static void wpi_free_fw_dma(wpi_sc_t *); static int wpi_alloc_rx_ring(wpi_sc_t *); static void wpi_reset_rx_ring(wpi_sc_t *); static void wpi_free_rx_ring(wpi_sc_t *); static int wpi_alloc_tx_ring(wpi_sc_t *, wpi_tx_ring_t *, int, int); static void wpi_reset_tx_ring(wpi_sc_t *, wpi_tx_ring_t *); static void wpi_free_tx_ring(wpi_sc_t *, wpi_tx_ring_t *); static ieee80211_node_t *wpi_node_alloc(ieee80211com_t *); static void wpi_node_free(ieee80211_node_t *); static int wpi_newstate(ieee80211com_t *, enum ieee80211_state, int); static int wpi_key_set(ieee80211com_t *, const struct ieee80211_key *, const uint8_t mac[IEEE80211_ADDR_LEN]); static void wpi_mem_lock(wpi_sc_t *); static void wpi_mem_unlock(wpi_sc_t *); static uint32_t wpi_mem_read(wpi_sc_t *, uint16_t); static void wpi_mem_write(wpi_sc_t *, uint16_t, uint32_t); static void wpi_mem_write_region_4(wpi_sc_t *, uint16_t, const uint32_t *, int); static uint16_t wpi_read_prom_word(wpi_sc_t *, uint32_t); static int wpi_load_microcode(wpi_sc_t *); static int wpi_load_firmware(wpi_sc_t *, uint32_t); static void wpi_rx_intr(wpi_sc_t *, wpi_rx_desc_t *, wpi_rx_data_t *); static void wpi_tx_intr(wpi_sc_t *, wpi_rx_desc_t *, wpi_rx_data_t *); static void wpi_cmd_intr(wpi_sc_t *, wpi_rx_desc_t *); static uint_t wpi_intr(caddr_t); static uint_t wpi_notif_softintr(caddr_t); static uint8_t wpi_plcp_signal(int); static void wpi_read_eeprom(wpi_sc_t *); static int wpi_cmd(wpi_sc_t *, int, const void *, int, int); static int wpi_mrr_setup(wpi_sc_t *); static void wpi_set_led(wpi_sc_t *, uint8_t, uint8_t, uint8_t); static int wpi_auth(wpi_sc_t *); static int wpi_scan(wpi_sc_t *); static int wpi_config(wpi_sc_t *); static void wpi_stop_master(wpi_sc_t *); static int wpi_power_up(wpi_sc_t *); static int wpi_reset(wpi_sc_t *); static void wpi_hw_config(wpi_sc_t *); static int wpi_init(wpi_sc_t *); static void wpi_stop(wpi_sc_t *); static void wpi_amrr_init(wpi_amrr_t *); static void wpi_amrr_timeout(wpi_sc_t *); static void wpi_amrr_ratectl(void *, ieee80211_node_t *); static int wpi_attach(dev_info_t *dip, ddi_attach_cmd_t cmd); static int wpi_detach(dev_info_t *dip, ddi_detach_cmd_t cmd); /* * GLD specific operations */ static int wpi_m_stat(void *arg, uint_t stat, uint64_t *val); static int wpi_m_start(void *arg); static void wpi_m_stop(void *arg); static int wpi_m_unicst(void *arg, const uint8_t *macaddr); static int wpi_m_multicst(void *arg, boolean_t add, const uint8_t *m); static int wpi_m_promisc(void *arg, boolean_t on); static mblk_t *wpi_m_tx(void *arg, mblk_t *mp); static void wpi_m_ioctl(void *arg, queue_t *wq, mblk_t *mp); static void wpi_destroy_locks(wpi_sc_t *sc); static int wpi_send(ieee80211com_t *ic, mblk_t *mp, uint8_t type); static void wpi_thread(wpi_sc_t *sc); /* * Supported rates for 802.11a/b/g modes (in 500Kbps unit). */ static const struct ieee80211_rateset wpi_rateset_11b = { 4, { 2, 4, 11, 22 } }; static const struct ieee80211_rateset wpi_rateset_11g = { 12, { 2, 4, 11, 22, 12, 18, 24, 36, 48, 72, 96, 108 } }; static const uint8_t wpi_ridx_to_signal[] = { /* OFDM: IEEE Std 802.11a-1999, pp. 14 Table 80 */ /* R1-R4 (ral/ural is R4-R1) */ 0xd, 0xf, 0x5, 0x7, 0x9, 0xb, 0x1, 0x3, /* CCK: device-dependent */ 10, 20, 55, 110 }; /* * For mfthread only */ extern pri_t minclsyspri; /* * Module Loading Data & Entry Points */ DDI_DEFINE_STREAM_OPS(wpi_devops, nulldev, nulldev, wpi_attach, wpi_detach, nodev, NULL, D_MP, NULL); static struct modldrv wpi_modldrv = { &mod_driverops, "Intel(R) PRO/Wireless 3945ABG driver", &wpi_devops }; static struct modlinkage wpi_modlinkage = { MODREV_1, &wpi_modldrv, NULL }; int _init(void) { int status; status = ddi_soft_state_init(&wpi_soft_state_p, sizeof (wpi_sc_t), 1); if (status != DDI_SUCCESS) return (status); mac_init_ops(&wpi_devops, "wpi"); status = mod_install(&wpi_modlinkage); if (status != DDI_SUCCESS) { mac_fini_ops(&wpi_devops); ddi_soft_state_fini(&wpi_soft_state_p); } return (status); } int _fini(void) { int status; status = mod_remove(&wpi_modlinkage); if (status == DDI_SUCCESS) { mac_fini_ops(&wpi_devops); ddi_soft_state_fini(&wpi_soft_state_p); } return (status); } int _info(struct modinfo *mip) { return (mod_info(&wpi_modlinkage, mip)); } /* * Mac Call Back entries */ mac_callbacks_t wpi_m_callbacks = { MC_IOCTL, wpi_m_stat, wpi_m_start, wpi_m_stop, wpi_m_promisc, wpi_m_multicst, wpi_m_unicst, wpi_m_tx, NULL, wpi_m_ioctl }; #ifdef DEBUG void wpi_dbg(uint32_t flags, const char *fmt, ...) { va_list ap; if (flags & wpi_dbg_flags) { va_start(ap, fmt); vcmn_err(CE_NOTE, fmt, ap); va_end(ap); } } #endif /* * device operations */ int wpi_attach(dev_info_t *dip, ddi_attach_cmd_t cmd) { wpi_sc_t *sc; ddi_acc_handle_t cfg_handle; caddr_t cfg_base; ieee80211com_t *ic; int instance, err, i; char strbuf[32]; wifi_data_t wd = { 0 }; mac_register_t *macp; switch (cmd) { case DDI_ATTACH: break; case DDI_RESUME: sc = ddi_get_soft_state(wpi_soft_state_p, ddi_get_instance(dip)); ASSERT(sc != NULL); mutex_enter(&sc->sc_glock); sc->sc_flags &= ~WPI_F_SUSPEND; mutex_exit(&sc->sc_glock); if (sc->sc_flags & WPI_F_RUNNING) { (void) wpi_init(sc); ieee80211_new_state(&sc->sc_ic, IEEE80211_S_INIT, -1); } WPI_DBG((WPI_DEBUG_RESUME, "wpi: resume \n")); return (DDI_SUCCESS); default: err = DDI_FAILURE; goto attach_fail1; } instance = ddi_get_instance(dip); err = ddi_soft_state_zalloc(wpi_soft_state_p, instance); if (err != DDI_SUCCESS) { cmn_err(CE_WARN, "wpi_attach(): failed to allocate soft state\n"); goto attach_fail1; } sc = ddi_get_soft_state(wpi_soft_state_p, instance); sc->sc_dip = dip; err = ddi_regs_map_setup(dip, 0, &cfg_base, 0, 0, &wpi_reg_accattr, &cfg_handle); if (err != DDI_SUCCESS) { cmn_err(CE_WARN, "wpi_attach(): failed to map config spaces regs\n"); goto attach_fail2; } sc->sc_rev = ddi_get8(cfg_handle, (uint8_t *)(cfg_base + PCI_CONF_REVID)); ddi_put8(cfg_handle, (uint8_t *)(cfg_base + 0x41), 0); sc->sc_clsz = ddi_get16(cfg_handle, (uint16_t *)(cfg_base + PCI_CONF_CACHE_LINESZ)); ddi_regs_map_free(&cfg_handle); if (!sc->sc_clsz) sc->sc_clsz = 16; sc->sc_clsz = (sc->sc_clsz << 2); sc->sc_dmabuf_sz = roundup(0x1000 + sizeof (struct ieee80211_frame) + IEEE80211_MTU + IEEE80211_CRC_LEN + (IEEE80211_WEP_IVLEN + IEEE80211_WEP_KIDLEN + IEEE80211_WEP_CRCLEN), sc->sc_clsz); /* * Map operating registers */ err = ddi_regs_map_setup(dip, 1, &sc->sc_base, 0, 0, &wpi_reg_accattr, &sc->sc_handle); if (err != DDI_SUCCESS) { cmn_err(CE_WARN, "wpi_attach(): failed to map device regs\n"); goto attach_fail2; } /* * Allocate shared page. */ err = wpi_alloc_shared(sc); if (err != DDI_SUCCESS) { cmn_err(CE_WARN, "failed to allocate shared page\n"); goto attach_fail3; } /* * Get the hw conf, including MAC address, then init all rings. */ wpi_read_eeprom(sc); err = wpi_ring_init(sc); if (err != DDI_SUCCESS) { cmn_err(CE_WARN, "wpi_attach(): " "failed to allocate and initialize ring\n"); goto attach_fail4; } sc->sc_hdr = (const wpi_firmware_hdr_t *)wpi_fw_bin; /* firmware image layout: |HDR|<--TEXT-->|<--DATA-->|<--BOOT-->| */ sc->sc_text = (const char *)(sc->sc_hdr + 1); sc->sc_data = sc->sc_text + LE_32(sc->sc_hdr->textsz); sc->sc_boot = sc->sc_data + LE_32(sc->sc_hdr->datasz); err = wpi_alloc_fw_dma(sc); if (err != DDI_SUCCESS) { cmn_err(CE_WARN, "wpi_attach(): " "failed to allocate firmware dma\n"); goto attach_fail5; } /* * Initialize mutexs and condvars */ err = ddi_get_iblock_cookie(dip, 0, &sc->sc_iblk); if (err != DDI_SUCCESS) { cmn_err(CE_WARN, "wpi_attach(): failed to do ddi_get_iblock_cookie()\n"); goto attach_fail6; } mutex_init(&sc->sc_glock, NULL, MUTEX_DRIVER, sc->sc_iblk); mutex_init(&sc->sc_tx_lock, NULL, MUTEX_DRIVER, sc->sc_iblk); cv_init(&sc->sc_fw_cv, NULL, CV_DRIVER, NULL); cv_init(&sc->sc_cmd_cv, NULL, CV_DRIVER, NULL); cv_init(&sc->sc_tx_cv, "tx-ring", CV_DRIVER, NULL); /* * initialize the mfthread */ mutex_init(&sc->sc_mt_lock, NULL, MUTEX_DRIVER, (void *) sc->sc_iblk); cv_init(&sc->sc_mt_cv, NULL, CV_DRIVER, NULL); sc->sc_mf_thread = NULL; sc->sc_mf_thread_switch = 0; /* * Initialize the wifi part, which will be used by * generic layer */ ic = &sc->sc_ic; ic->ic_phytype = IEEE80211_T_OFDM; ic->ic_opmode = IEEE80211_M_STA; /* default to BSS mode */ ic->ic_state = IEEE80211_S_INIT; ic->ic_maxrssi = 70; /* experimental number */ ic->ic_caps = IEEE80211_C_SHPREAMBLE | IEEE80211_C_TXPMGT | IEEE80211_C_PMGT | IEEE80211_C_SHSLOT; /* * use software WEP and TKIP, hardware CCMP; */ ic->ic_caps |= IEEE80211_C_AES_CCM; ic->ic_caps |= IEEE80211_C_WPA; /* Support WPA/WPA2 */ /* set supported .11b and .11g rates */ ic->ic_sup_rates[IEEE80211_MODE_11B] = wpi_rateset_11b; ic->ic_sup_rates[IEEE80211_MODE_11G] = wpi_rateset_11g; /* set supported .11b and .11g channels (1 through 14) */ for (i = 1; i <= 14; i++) { ic->ic_sup_channels[i].ich_freq = ieee80211_ieee2mhz(i, IEEE80211_CHAN_2GHZ); ic->ic_sup_channels[i].ich_flags = IEEE80211_CHAN_CCK | IEEE80211_CHAN_OFDM | IEEE80211_CHAN_DYN | IEEE80211_CHAN_2GHZ; } ic->ic_ibss_chan = &ic->ic_sup_channels[0]; ic->ic_xmit = wpi_send; /* * init Wifi layer */ ieee80211_attach(ic); /* register WPA door */ ieee80211_register_door(ic, ddi_driver_name(dip), ddi_get_instance(dip)); /* * Override 80211 default routines */ sc->sc_newstate = ic->ic_newstate; ic->ic_newstate = wpi_newstate; ic->ic_node_alloc = wpi_node_alloc; ic->ic_node_free = wpi_node_free; ic->ic_crypto.cs_key_set = wpi_key_set; ieee80211_media_init(ic); /* * initialize default tx key */ ic->ic_def_txkey = 0; err = ddi_add_softintr(dip, DDI_SOFTINT_LOW, &sc->sc_notif_softint_id, &sc->sc_iblk, NULL, wpi_notif_softintr, (caddr_t)sc); if (err != DDI_SUCCESS) { cmn_err(CE_WARN, "wpi_attach(): failed to do ddi_add_softintr()\n"); goto attach_fail7; } /* * Add the interrupt handler */ err = ddi_add_intr(dip, 0, &sc->sc_iblk, NULL, wpi_intr, (caddr_t)sc); if (err != DDI_SUCCESS) { cmn_err(CE_WARN, "wpi_attach(): failed to do ddi_add_intr()\n"); goto attach_fail8; } /* * Initialize pointer to device specific functions */ wd.wd_secalloc = WIFI_SEC_NONE; wd.wd_opmode = ic->ic_opmode; IEEE80211_ADDR_COPY(wd.wd_bssid, ic->ic_macaddr); macp = mac_alloc(MAC_VERSION); if (err != DDI_SUCCESS) { cmn_err(CE_WARN, "wpi_attach(): failed to do mac_alloc()\n"); goto attach_fail9; } macp->m_type_ident = MAC_PLUGIN_IDENT_WIFI; macp->m_driver = sc; macp->m_dip = dip; macp->m_src_addr = ic->ic_macaddr; macp->m_callbacks = &wpi_m_callbacks; macp->m_min_sdu = 0; macp->m_max_sdu = IEEE80211_MTU; macp->m_pdata = &wd; macp->m_pdata_size = sizeof (wd); /* * Register the macp to mac */ err = mac_register(macp, &ic->ic_mach); mac_free(macp); if (err != DDI_SUCCESS) { cmn_err(CE_WARN, "wpi_attach(): failed to do mac_register()\n"); goto attach_fail9; } /* * Create minor node of type DDI_NT_NET_WIFI */ (void) snprintf(strbuf, sizeof (strbuf), "wpi%d", instance); err = ddi_create_minor_node(dip, strbuf, S_IFCHR, instance + 1, DDI_NT_NET_WIFI, 0); if (err != DDI_SUCCESS) cmn_err(CE_WARN, "wpi_attach(): failed to do ddi_create_minor_node()\n"); /* * Notify link is down now */ mac_link_update(ic->ic_mach, LINK_STATE_DOWN); /* * create the mf thread to handle the link status, * recovery fatal error, etc. */ sc->sc_mf_thread_switch = 1; if (sc->sc_mf_thread == NULL) sc->sc_mf_thread = thread_create((caddr_t)NULL, 0, wpi_thread, sc, 0, &p0, TS_RUN, minclsyspri); sc->sc_flags |= WPI_F_ATTACHED; return (DDI_SUCCESS); attach_fail9: ddi_remove_intr(dip, 0, sc->sc_iblk); attach_fail8: ddi_remove_softintr(sc->sc_notif_softint_id); sc->sc_notif_softint_id = NULL; attach_fail7: ieee80211_detach(ic); wpi_destroy_locks(sc); attach_fail6: wpi_free_fw_dma(sc); attach_fail5: wpi_ring_free(sc); attach_fail4: wpi_free_shared(sc); attach_fail3: ddi_regs_map_free(&sc->sc_handle); attach_fail2: ddi_soft_state_free(wpi_soft_state_p, instance); attach_fail1: return (err); } int wpi_detach(dev_info_t *dip, ddi_detach_cmd_t cmd) { wpi_sc_t *sc; int err; sc = ddi_get_soft_state(wpi_soft_state_p, ddi_get_instance(dip)); ASSERT(sc != NULL); switch (cmd) { case DDI_DETACH: break; case DDI_SUSPEND: if (sc->sc_flags & WPI_F_RUNNING) { wpi_stop(sc); } mutex_enter(&sc->sc_glock); sc->sc_flags |= WPI_F_SUSPEND; mutex_exit(&sc->sc_glock); WPI_DBG((WPI_DEBUG_RESUME, "wpi: suspend \n")); return (DDI_SUCCESS); default: return (DDI_FAILURE); } if (!(sc->sc_flags & WPI_F_ATTACHED)) return (DDI_FAILURE); /* * Destroy the mf_thread */ mutex_enter(&sc->sc_mt_lock); sc->sc_mf_thread_switch = 0; while (sc->sc_mf_thread != NULL) { if (cv_wait_sig(&sc->sc_mt_cv, &sc->sc_mt_lock) == 0) break; } mutex_exit(&sc->sc_mt_lock); wpi_stop(sc); /* * Unregiste from the MAC layer subsystem */ err = mac_unregister(sc->sc_ic.ic_mach); if (err != DDI_SUCCESS) return (err); mutex_enter(&sc->sc_glock); wpi_free_fw_dma(sc); wpi_ring_free(sc); wpi_free_shared(sc); mutex_exit(&sc->sc_glock); ddi_remove_intr(dip, 0, sc->sc_iblk); ddi_remove_softintr(sc->sc_notif_softint_id); sc->sc_notif_softint_id = NULL; /* * detach ieee80211 */ ieee80211_detach(&sc->sc_ic); wpi_destroy_locks(sc); ddi_regs_map_free(&sc->sc_handle); ddi_remove_minor_node(dip, NULL); ddi_soft_state_free(wpi_soft_state_p, ddi_get_instance(dip)); return (DDI_SUCCESS); } static void wpi_destroy_locks(wpi_sc_t *sc) { cv_destroy(&sc->sc_mt_cv); mutex_destroy(&sc->sc_mt_lock); cv_destroy(&sc->sc_tx_cv); cv_destroy(&sc->sc_cmd_cv); cv_destroy(&sc->sc_fw_cv); mutex_destroy(&sc->sc_tx_lock); mutex_destroy(&sc->sc_glock); } /* * Allocate an area of memory and a DMA handle for accessing it */ static int wpi_alloc_dma_mem(wpi_sc_t *sc, size_t memsize, ddi_dma_attr_t *dma_attr_p, ddi_device_acc_attr_t *acc_attr_p, uint_t dma_flags, wpi_dma_t *dma_p) { caddr_t vaddr; int err; /* * Allocate handle */ err = ddi_dma_alloc_handle(sc->sc_dip, dma_attr_p, DDI_DMA_SLEEP, NULL, &dma_p->dma_hdl); if (err != DDI_SUCCESS) { dma_p->dma_hdl = NULL; return (DDI_FAILURE); } /* * Allocate memory */ err = ddi_dma_mem_alloc(dma_p->dma_hdl, memsize, acc_attr_p, dma_flags & (DDI_DMA_CONSISTENT | DDI_DMA_STREAMING), DDI_DMA_SLEEP, NULL, &vaddr, &dma_p->alength, &dma_p->acc_hdl); if (err != DDI_SUCCESS) { ddi_dma_free_handle(&dma_p->dma_hdl); dma_p->dma_hdl = NULL; dma_p->acc_hdl = NULL; return (DDI_FAILURE); } /* * Bind the two together */ dma_p->mem_va = vaddr; err = ddi_dma_addr_bind_handle(dma_p->dma_hdl, NULL, vaddr, dma_p->alength, dma_flags, DDI_DMA_SLEEP, NULL, &dma_p->cookie, &dma_p->ncookies); if (err != DDI_DMA_MAPPED) { ddi_dma_mem_free(&dma_p->acc_hdl); ddi_dma_free_handle(&dma_p->dma_hdl); dma_p->acc_hdl = NULL; dma_p->dma_hdl = NULL; return (DDI_FAILURE); } dma_p->nslots = ~0U; dma_p->size = ~0U; dma_p->token = ~0U; dma_p->offset = 0; return (DDI_SUCCESS); } /* * Free one allocated area of DMAable memory */ static void wpi_free_dma_mem(wpi_dma_t *dma_p) { if (dma_p->dma_hdl != NULL) { if (dma_p->ncookies) { (void) ddi_dma_unbind_handle(dma_p->dma_hdl); dma_p->ncookies = 0; } ddi_dma_free_handle(&dma_p->dma_hdl); dma_p->dma_hdl = NULL; } if (dma_p->acc_hdl != NULL) { ddi_dma_mem_free(&dma_p->acc_hdl); dma_p->acc_hdl = NULL; } } /* * Allocate an area of dma memory for firmware load. * Idealy, this allocation should be a one time action, that is, * the memory will be freed after the firmware is uploaded to the * card. but since a recovery mechanism for the fatal firmware need * reload the firmware, and re-allocate dma at run time may be failed, * so we allocate it at attach and keep it in the whole lifecycle of * the driver. */ static int wpi_alloc_fw_dma(wpi_sc_t *sc) { int i, err = DDI_SUCCESS; wpi_dma_t *dma_p; err = wpi_alloc_dma_mem(sc, LE_32(sc->sc_hdr->textsz), &fw_buffer_dma_attr, &wpi_dma_accattr, DDI_DMA_RDWR | DDI_DMA_CONSISTENT, &sc->sc_dma_fw_text); dma_p = &sc->sc_dma_fw_text; WPI_DBG((WPI_DEBUG_DMA, "ncookies:%d addr1:%x size1:%x\n", dma_p->ncookies, dma_p->cookie.dmac_address, dma_p->cookie.dmac_size)); if (err != DDI_SUCCESS) { cmn_err(CE_WARN, "wpi_alloc_fw_dma(): failed to alloc" "text dma memory"); goto fail; } for (i = 0; i < dma_p->ncookies; i++) { sc->sc_fw_text_cookie[i] = dma_p->cookie; ddi_dma_nextcookie(dma_p->dma_hdl, &dma_p->cookie); } err = wpi_alloc_dma_mem(sc, LE_32(sc->sc_hdr->datasz), &fw_buffer_dma_attr, &wpi_dma_accattr, DDI_DMA_RDWR | DDI_DMA_CONSISTENT, &sc->sc_dma_fw_data); dma_p = &sc->sc_dma_fw_data; WPI_DBG((WPI_DEBUG_DMA, "ncookies:%d addr1:%x size1:%x\n", dma_p->ncookies, dma_p->cookie.dmac_address, dma_p->cookie.dmac_size)); if (err != DDI_SUCCESS) { cmn_err(CE_WARN, "wpi_alloc_fw_dma(): failed to alloc" "data dma memory"); goto fail; } for (i = 0; i < dma_p->ncookies; i++) { sc->sc_fw_data_cookie[i] = dma_p->cookie; ddi_dma_nextcookie(dma_p->dma_hdl, &dma_p->cookie); } fail: return (err); } static void wpi_free_fw_dma(wpi_sc_t *sc) { wpi_free_dma_mem(&sc->sc_dma_fw_text); wpi_free_dma_mem(&sc->sc_dma_fw_data); } /* * Allocate a shared page between host and NIC. */ static int wpi_alloc_shared(wpi_sc_t *sc) { int err = DDI_SUCCESS; /* must be aligned on a 4K-page boundary */ err = wpi_alloc_dma_mem(sc, sizeof (wpi_shared_t), &sh_dma_attr, &wpi_dma_accattr, DDI_DMA_RDWR | DDI_DMA_CONSISTENT, &sc->sc_dma_sh); if (err != DDI_SUCCESS) goto fail; sc->sc_shared = (wpi_shared_t *)sc->sc_dma_sh.mem_va; return (err); fail: wpi_free_shared(sc); return (err); } static void wpi_free_shared(wpi_sc_t *sc) { wpi_free_dma_mem(&sc->sc_dma_sh); } static int wpi_alloc_rx_ring(wpi_sc_t *sc) { wpi_rx_ring_t *ring; wpi_rx_data_t *data; int i, err = DDI_SUCCESS; ring = &sc->sc_rxq; ring->cur = 0; err = wpi_alloc_dma_mem(sc, WPI_RX_RING_COUNT * sizeof (uint32_t), &ring_desc_dma_attr, &wpi_dma_accattr, DDI_DMA_RDWR | DDI_DMA_CONSISTENT, &ring->dma_desc); if (err != DDI_SUCCESS) { WPI_DBG((WPI_DEBUG_DMA, "dma alloc rx ring desc failed\n")); goto fail; } ring->desc = (uint32_t *)ring->dma_desc.mem_va; /* * Allocate Rx buffers. */ for (i = 0; i < WPI_RX_RING_COUNT; i++) { data = &ring->data[i]; err = wpi_alloc_dma_mem(sc, sc->sc_dmabuf_sz, &rx_buffer_dma_attr, &wpi_dma_accattr, DDI_DMA_READ | DDI_DMA_STREAMING, &data->dma_data); if (err != DDI_SUCCESS) { WPI_DBG((WPI_DEBUG_DMA, "dma alloc rx ring buf[%d] " "failed\n", i)); goto fail; } ring->desc[i] = LE_32(data->dma_data.cookie.dmac_address); } WPI_DMA_SYNC(ring->dma_desc, DDI_DMA_SYNC_FORDEV); return (err); fail: wpi_free_rx_ring(sc); return (err); } static void wpi_reset_rx_ring(wpi_sc_t *sc) { int ntries; wpi_mem_lock(sc); WPI_WRITE(sc, WPI_RX_CONFIG, 0); for (ntries = 0; ntries < 2000; ntries++) { if (WPI_READ(sc, WPI_RX_STATUS) & WPI_RX_IDLE) break; DELAY(1000); } #ifdef DEBUG if (ntries == 2000) WPI_DBG((WPI_DEBUG_DMA, "timeout resetting Rx ring\n")); #endif wpi_mem_unlock(sc); sc->sc_rxq.cur = 0; } static void wpi_free_rx_ring(wpi_sc_t *sc) { int i; for (i = 0; i < WPI_RX_RING_COUNT; i++) { if (sc->sc_rxq.data[i].dma_data.dma_hdl) WPI_DMA_SYNC(sc->sc_rxq.data[i].dma_data, DDI_DMA_SYNC_FORCPU); wpi_free_dma_mem(&sc->sc_rxq.data[i].dma_data); } if (sc->sc_rxq.dma_desc.dma_hdl) WPI_DMA_SYNC(sc->sc_rxq.dma_desc, DDI_DMA_SYNC_FORDEV); wpi_free_dma_mem(&sc->sc_rxq.dma_desc); } static int wpi_alloc_tx_ring(wpi_sc_t *sc, wpi_tx_ring_t *ring, int count, int qid) { wpi_tx_data_t *data; wpi_tx_desc_t *desc_h; uint32_t paddr_desc_h; wpi_tx_cmd_t *cmd_h; uint32_t paddr_cmd_h; int i, err = DDI_SUCCESS; ring->qid = qid; ring->count = count; ring->queued = 0; ring->cur = 0; err = wpi_alloc_dma_mem(sc, count * sizeof (wpi_tx_desc_t), &ring_desc_dma_attr, &wpi_dma_accattr, DDI_DMA_RDWR | DDI_DMA_CONSISTENT, &ring->dma_desc); if (err != DDI_SUCCESS) { WPI_DBG((WPI_DEBUG_DMA, "dma alloc tx ring desc[%d] failed\n", qid)); goto fail; } /* update shared page with ring's base address */ sc->sc_shared->txbase[qid] = ring->dma_desc.cookie.dmac_address; desc_h = (wpi_tx_desc_t *)ring->dma_desc.mem_va; paddr_desc_h = ring->dma_desc.cookie.dmac_address; err = wpi_alloc_dma_mem(sc, count * sizeof (wpi_tx_cmd_t), &tx_cmd_dma_attr, &wpi_dma_accattr, DDI_DMA_RDWR | DDI_DMA_CONSISTENT, &ring->dma_cmd); if (err != DDI_SUCCESS) { WPI_DBG((WPI_DEBUG_DMA, "dma alloc tx ring cmd[%d] failed\n", qid)); goto fail; } cmd_h = (wpi_tx_cmd_t *)ring->dma_cmd.mem_va; paddr_cmd_h = ring->dma_cmd.cookie.dmac_address; /* * Allocate Tx buffers. */ ring->data = kmem_zalloc(sizeof (wpi_tx_data_t) * count, KM_NOSLEEP); if (ring->data == NULL) { WPI_DBG((WPI_DEBUG_DMA, "could not allocate tx data slots\n")); goto fail; } for (i = 0; i < count; i++) { data = &ring->data[i]; err = wpi_alloc_dma_mem(sc, sc->sc_dmabuf_sz, &tx_buffer_dma_attr, &wpi_dma_accattr, DDI_DMA_WRITE | DDI_DMA_STREAMING, &data->dma_data); if (err != DDI_SUCCESS) { WPI_DBG((WPI_DEBUG_DMA, "dma alloc tx ring buf[%d] " "failed\n", i)); goto fail; } data->desc = desc_h + i; data->paddr_desc = paddr_desc_h + ((uintptr_t)data->desc - (uintptr_t)desc_h); data->cmd = cmd_h + i; data->paddr_cmd = paddr_cmd_h + ((uintptr_t)data->cmd - (uintptr_t)cmd_h); } return (err); fail: if (ring->data) kmem_free(ring->data, sizeof (wpi_tx_data_t) * count); wpi_free_tx_ring(sc, ring); return (err); } static void wpi_reset_tx_ring(wpi_sc_t *sc, wpi_tx_ring_t *ring) { wpi_tx_data_t *data; int i, ntries; wpi_mem_lock(sc); WPI_WRITE(sc, WPI_TX_CONFIG(ring->qid), 0); for (ntries = 0; ntries < 100; ntries++) { if (WPI_READ(sc, WPI_TX_STATUS) & WPI_TX_IDLE(ring->qid)) break; DELAY(10); } #ifdef DEBUG if (ntries == 100 && wpi_dbg_flags > 0) { WPI_DBG((WPI_DEBUG_DMA, "timeout resetting Tx ring %d\n", ring->qid)); } #endif wpi_mem_unlock(sc); for (i = 0; i < ring->count; i++) { data = &ring->data[i]; WPI_DMA_SYNC(data->dma_data, DDI_DMA_SYNC_FORDEV); } ring->queued = 0; ring->cur = 0; } /*ARGSUSED*/ static void wpi_free_tx_ring(wpi_sc_t *sc, wpi_tx_ring_t *ring) { int i; if (ring->dma_desc.dma_hdl != NULL) WPI_DMA_SYNC(ring->dma_desc, DDI_DMA_SYNC_FORDEV); wpi_free_dma_mem(&ring->dma_desc); if (ring->dma_cmd.dma_hdl != NULL) WPI_DMA_SYNC(ring->dma_cmd, DDI_DMA_SYNC_FORDEV); wpi_free_dma_mem(&ring->dma_cmd); if (ring->data != NULL) { for (i = 0; i < ring->count; i++) { if (ring->data[i].dma_data.dma_hdl) WPI_DMA_SYNC(ring->data[i].dma_data, DDI_DMA_SYNC_FORDEV); wpi_free_dma_mem(&ring->data[i].dma_data); } kmem_free(ring->data, ring->count * sizeof (wpi_tx_data_t)); } } static int wpi_ring_init(wpi_sc_t *sc) { int i, err = DDI_SUCCESS; for (i = 0; i < 4; i++) { err = wpi_alloc_tx_ring(sc, &sc->sc_txq[i], WPI_TX_RING_COUNT, i); if (err != DDI_SUCCESS) goto fail; } err = wpi_alloc_tx_ring(sc, &sc->sc_cmdq, WPI_CMD_RING_COUNT, 4); if (err != DDI_SUCCESS) goto fail; err = wpi_alloc_tx_ring(sc, &sc->sc_svcq, WPI_SVC_RING_COUNT, 5); if (err != DDI_SUCCESS) goto fail; err = wpi_alloc_rx_ring(sc); if (err != DDI_SUCCESS) goto fail; return (err); fail: return (err); } static void wpi_ring_free(wpi_sc_t *sc) { int i = 4; wpi_free_rx_ring(sc); wpi_free_tx_ring(sc, &sc->sc_svcq); wpi_free_tx_ring(sc, &sc->sc_cmdq); while (--i >= 0) { wpi_free_tx_ring(sc, &sc->sc_txq[i]); } } /* ARGSUSED */ static ieee80211_node_t * wpi_node_alloc(ieee80211com_t *ic) { wpi_amrr_t *amrr; amrr = kmem_zalloc(sizeof (wpi_amrr_t), KM_SLEEP); if (amrr != NULL) wpi_amrr_init(amrr); return (&amrr->in); } static void wpi_node_free(ieee80211_node_t *in) { ieee80211com_t *ic = in->in_ic; ic->ic_node_cleanup(in); if (in->in_wpa_ie != NULL) ieee80211_free(in->in_wpa_ie); kmem_free(in, sizeof (wpi_amrr_t)); } /*ARGSUSED*/ static int wpi_newstate(ieee80211com_t *ic, enum ieee80211_state nstate, int arg) { wpi_sc_t *sc = (wpi_sc_t *)ic; ieee80211_node_t *in = ic->ic_bss; enum ieee80211_state ostate; int i, err = WPI_SUCCESS; mutex_enter(&sc->sc_glock); switch (nstate) { case IEEE80211_S_SCAN: ostate = ic->ic_state; switch (ostate) { default: break; case IEEE80211_S_INIT: /* make the link LED blink while we're scanning */ wpi_set_led(sc, WPI_LED_LINK, 20, 2); ic->ic_flags |= IEEE80211_F_SCAN | IEEE80211_F_ASCAN; if ((err = wpi_scan(sc)) != 0) { WPI_DBG((WPI_DEBUG_80211, "could not initiate scan\n")); ic->ic_flags &= ~(IEEE80211_F_SCAN | IEEE80211_F_ASCAN); mutex_exit(&sc->sc_glock); return (err); } break; } ic->ic_state = nstate; sc->sc_clk = 0; mutex_exit(&sc->sc_glock); return (WPI_SUCCESS); case IEEE80211_S_AUTH: /* reset state to handle reassociations correctly */ sc->sc_config.state = 0; sc->sc_config.filter &= ~LE_32(WPI_FILTER_BSS); if ((err = wpi_auth(sc)) != 0) { WPI_DBG((WPI_DEBUG_80211, "could not send authentication request\n")); mutex_exit(&sc->sc_glock); return (err); } break; case IEEE80211_S_RUN: if (ic->ic_opmode == IEEE80211_M_MONITOR) { /* link LED blinks while monitoring */ wpi_set_led(sc, WPI_LED_LINK, 5, 5); break; } if (ic->ic_opmode != IEEE80211_M_STA) { (void) wpi_auth(sc); /* need setup beacon here */ } WPI_DBG((WPI_DEBUG_80211, "wpi: associated.")); /* update adapter's configuration */ sc->sc_config.state = LE_16(WPI_CONFIG_ASSOCIATED); /* short preamble/slot time are negotiated when associating */ sc->sc_config.flags &= ~LE_32(WPI_CONFIG_SHPREAMBLE | WPI_CONFIG_SHSLOT); if (ic->ic_flags & IEEE80211_F_SHSLOT) sc->sc_config.flags |= LE_32(WPI_CONFIG_SHSLOT); if (ic->ic_flags & IEEE80211_F_SHPREAMBLE) sc->sc_config.flags |= LE_32(WPI_CONFIG_SHPREAMBLE); sc->sc_config.filter |= LE_32(WPI_FILTER_BSS); if (ic->ic_opmode != IEEE80211_M_STA) sc->sc_config.filter |= LE_32(WPI_FILTER_BEACON); WPI_DBG((WPI_DEBUG_80211, "config chan %d flags %x\n", sc->sc_config.chan, sc->sc_config.flags)); err = wpi_cmd(sc, WPI_CMD_CONFIGURE, &sc->sc_config, sizeof (wpi_config_t), 1); if (err != WPI_SUCCESS) { WPI_DBG((WPI_DEBUG_80211, "could not update configuration\n")); mutex_exit(&sc->sc_glock); return (err); } /* start automatic rate control */ mutex_enter(&sc->sc_mt_lock); if (ic->ic_fixed_rate == IEEE80211_FIXED_RATE_NONE) { sc->sc_flags |= WPI_F_RATE_AUTO_CTL; /* set rate to some reasonable initial value */ i = in->in_rates.ir_nrates - 1; while (i > 0 && IEEE80211_RATE(i) > 72) i--; in->in_txrate = i; } else { sc->sc_flags &= ~WPI_F_RATE_AUTO_CTL; } mutex_exit(&sc->sc_mt_lock); /* link LED always on while associated */ wpi_set_led(sc, WPI_LED_LINK, 0, 1); break; case IEEE80211_S_INIT: case IEEE80211_S_ASSOC: break; } mutex_exit(&sc->sc_glock); return (sc->sc_newstate(ic, nstate, arg)); } /*ARGSUSED*/ static int wpi_key_set(ieee80211com_t *ic, const struct ieee80211_key *k, const uint8_t mac[IEEE80211_ADDR_LEN]) { wpi_sc_t *sc = (wpi_sc_t *)ic; wpi_node_t node; int err; switch (k->wk_cipher->ic_cipher) { case IEEE80211_CIPHER_WEP: case IEEE80211_CIPHER_TKIP: return (1); /* sofeware do it. */ case IEEE80211_CIPHER_AES_CCM: break; default: return (0); } sc->sc_config.filter &= ~(WPI_FILTER_NODECRYPTUNI | WPI_FILTER_NODECRYPTMUL); mutex_enter(&sc->sc_glock); /* update ap/multicast node */ (void) memset(&node, 0, sizeof (node)); if (IEEE80211_IS_MULTICAST(mac)) { (void) memset(node.bssid, 0xff, 6); node.id = WPI_ID_BROADCAST; } else { IEEE80211_ADDR_COPY(node.bssid, ic->ic_bss->in_bssid); node.id = WPI_ID_BSS; } if (k->wk_flags & IEEE80211_KEY_XMIT) { node.key_flags = 0; node.keyp = k->wk_keyix; } else { node.key_flags = (1 << 14); node.keyp = k->wk_keyix + 4; } (void) memcpy(node.key, k->wk_key, k->wk_keylen); node.key_flags |= (2 | (1 << 3) | (k->wk_keyix << 8)); node.sta_mask = 1; node.control = 1; err = wpi_cmd(sc, WPI_CMD_ADD_NODE, &node, sizeof (node), 1); if (err != WPI_SUCCESS) { cmn_err(CE_WARN, "wpi_key_set():" "failed to update ap node\n"); mutex_exit(&sc->sc_glock); return (0); } mutex_exit(&sc->sc_glock); return (1); } /* * Grab exclusive access to NIC memory. */ static void wpi_mem_lock(wpi_sc_t *sc) { uint32_t tmp; int ntries; tmp = WPI_READ(sc, WPI_GPIO_CTL); WPI_WRITE(sc, WPI_GPIO_CTL, tmp | WPI_GPIO_MAC); /* spin until we actually get the lock */ for (ntries = 0; ntries < 1000; ntries++) { if ((WPI_READ(sc, WPI_GPIO_CTL) & (WPI_GPIO_CLOCK | WPI_GPIO_SLEEP)) == WPI_GPIO_CLOCK) break; DELAY(10); } if (ntries == 1000) WPI_DBG((WPI_DEBUG_PIO, "could not lock memory\n")); } /* * Release lock on NIC memory. */ static void wpi_mem_unlock(wpi_sc_t *sc) { uint32_t tmp = WPI_READ(sc, WPI_GPIO_CTL); WPI_WRITE(sc, WPI_GPIO_CTL, tmp & ~WPI_GPIO_MAC); } static uint32_t wpi_mem_read(wpi_sc_t *sc, uint16_t addr) { WPI_WRITE(sc, WPI_READ_MEM_ADDR, WPI_MEM_4 | addr); return (WPI_READ(sc, WPI_READ_MEM_DATA)); } static void wpi_mem_write(wpi_sc_t *sc, uint16_t addr, uint32_t data) { WPI_WRITE(sc, WPI_WRITE_MEM_ADDR, WPI_MEM_4 | addr); WPI_WRITE(sc, WPI_WRITE_MEM_DATA, data); } static void wpi_mem_write_region_4(wpi_sc_t *sc, uint16_t addr, const uint32_t *data, int wlen) { for (; wlen > 0; wlen--, data++, addr += 4) wpi_mem_write(sc, addr, *data); } /* * Read 16 bits from the EEPROM. We access EEPROM through the MAC instead of * using the traditional bit-bang method. */ static uint16_t wpi_read_prom_word(wpi_sc_t *sc, uint32_t addr) { uint32_t val; int ntries; WPI_WRITE(sc, WPI_EEPROM_CTL, addr << 2); wpi_mem_lock(sc); for (ntries = 0; ntries < 10; ntries++) { if ((val = WPI_READ(sc, WPI_EEPROM_CTL)) & WPI_EEPROM_READY) break; DELAY(10); } wpi_mem_unlock(sc); if (ntries == 10) { WPI_DBG((WPI_DEBUG_PIO, "could not read EEPROM\n")); return (0xdead); } return (val >> 16); } /* * The firmware boot code is small and is intended to be copied directly into * the NIC internal memory. */ static int wpi_load_microcode(wpi_sc_t *sc) { const char *ucode; int size; ucode = sc->sc_boot; size = LE_32(sc->sc_hdr->bootsz); /* check that microcode size is a multiple of 4 */ if (size & 3) return (EINVAL); size /= sizeof (uint32_t); wpi_mem_lock(sc); /* copy microcode image into NIC memory */ wpi_mem_write_region_4(sc, WPI_MEM_UCODE_BASE, (const uint32_t *)ucode, size); wpi_mem_write(sc, WPI_MEM_UCODE_SRC, 0); wpi_mem_write(sc, WPI_MEM_UCODE_DST, WPI_FW_TEXT); wpi_mem_write(sc, WPI_MEM_UCODE_SIZE, size); /* run microcode */ wpi_mem_write(sc, WPI_MEM_UCODE_CTL, WPI_UC_RUN); wpi_mem_unlock(sc); return (WPI_SUCCESS); } /* * The firmware text and data segments are transferred to the NIC using DMA. * The driver just copies the firmware into DMA-safe memory and tells the NIC * where to find it. Once the NIC has copied the firmware into its internal * memory, we can free our local copy in the driver. */ static int wpi_load_firmware(wpi_sc_t *sc, uint32_t target) { const char *fw; int size; wpi_dma_t *dma_p; ddi_dma_cookie_t *cookie; wpi_tx_desc_t desc; int i, ntries, err = WPI_SUCCESS; /* only text and data here */ if (target == WPI_FW_TEXT) { fw = sc->sc_text; size = LE_32(sc->sc_hdr->textsz); dma_p = &sc->sc_dma_fw_text; cookie = sc->sc_fw_text_cookie; } else { fw = sc->sc_data; size = LE_32(sc->sc_hdr->datasz); dma_p = &sc->sc_dma_fw_data; cookie = sc->sc_fw_data_cookie; } /* copy firmware image to DMA-safe memory */ (void) memcpy(dma_p->mem_va, fw, size); /* make sure the adapter will get up-to-date values */ (void) ddi_dma_sync(dma_p->dma_hdl, 0, size, DDI_DMA_SYNC_FORDEV); (void) memset(&desc, 0, sizeof (desc)); desc.flags = LE_32(WPI_PAD32(size) << 28 | dma_p->ncookies << 24); for (i = 0; i < dma_p->ncookies; i++) { WPI_DBG((WPI_DEBUG_DMA, "cookie%d addr:%x size:%x\n", i, cookie[i].dmac_address, cookie[i].dmac_size)); desc.segs[i].addr = cookie[i].dmac_address; desc.segs[i].len = (uint32_t)cookie[i].dmac_size; } wpi_mem_lock(sc); /* tell adapter where to copy image in its internal memory */ WPI_WRITE(sc, WPI_FW_TARGET, target); WPI_WRITE(sc, WPI_TX_CONFIG(6), 0); /* copy firmware descriptor into NIC memory */ WPI_WRITE_REGION_4(sc, WPI_TX_DESC(6), (uint32_t *)&desc, sizeof desc / sizeof (uint32_t)); WPI_WRITE(sc, WPI_TX_CREDIT(6), 0xfffff); WPI_WRITE(sc, WPI_TX_STATE(6), 0x4001); WPI_WRITE(sc, WPI_TX_CONFIG(6), 0x80000001); /* wait while the adapter is busy copying the firmware */ for (ntries = 0; ntries < 100; ntries++) { if (WPI_READ(sc, WPI_TX_STATUS) & WPI_TX_IDLE(6)) break; DELAY(1000); } if (ntries == 100) { WPI_DBG((WPI_DEBUG_FW, "timeout transferring firmware\n")); err = ETIMEDOUT; } WPI_WRITE(sc, WPI_TX_CREDIT(6), 0); wpi_mem_unlock(sc); return (err); } /*ARGSUSED*/ static void wpi_rx_intr(wpi_sc_t *sc, wpi_rx_desc_t *desc, wpi_rx_data_t *data) { ieee80211com_t *ic = &sc->sc_ic; wpi_rx_ring_t *ring = &sc->sc_rxq; wpi_rx_stat_t *stat; wpi_rx_head_t *head; wpi_rx_tail_t *tail; ieee80211_node_t *in; struct ieee80211_frame *wh; mblk_t *mp; uint16_t len; stat = (wpi_rx_stat_t *)(desc + 1); if (stat->len > WPI_STAT_MAXLEN) { WPI_DBG((WPI_DEBUG_RX, "invalid rx statistic header\n")); return; } head = (wpi_rx_head_t *)((caddr_t)(stat + 1) + stat->len); tail = (wpi_rx_tail_t *)((caddr_t)(head + 1) + LE_16(head->len)); len = LE_16(head->len); WPI_DBG((WPI_DEBUG_RX, "rx intr: idx=%d len=%d stat len=%d rssi=%d " "rate=%x chan=%d tstamp=%llu", ring->cur, LE_32(desc->len), len, (int8_t)stat->rssi, head->rate, head->chan, LE_64(tail->tstamp))); if ((len < 20) || (len > sc->sc_dmabuf_sz)) { sc->sc_rx_err++; return; } /* * Discard Rx frames with bad CRC early */ if ((LE_32(tail->flags) & WPI_RX_NOERROR) != WPI_RX_NOERROR) { WPI_DBG((WPI_DEBUG_RX, "rx tail flags error %x\n", LE_32(tail->flags))); sc->sc_rx_err++; return; } /* update Rx descriptor */ /* ring->desc[ring->cur] = LE_32(data->dma_data.cookie.dmac_address); */ #ifdef WPI_BPF #ifndef WPI_CURRENT if (sc->sc_drvbpf != NULL) { #else if (bpf_peers_present(sc->sc_drvbpf)) { #endif struct wpi_rx_radiotap_header *tap = &sc->sc_rxtap; tap->wr_flags = 0; tap->wr_rate = head->rate; tap->wr_chan_freq = LE_16(ic->ic_channels[head->chan].ic_freq); tap->wr_chan_flags = LE_16(ic->ic_channels[head->chan].ic_flags); tap->wr_dbm_antsignal = (int8_t)(stat->rssi - WPI_RSSI_OFFSET); tap->wr_dbm_antnoise = (int8_t)LE_16(stat->noise); tap->wr_tsft = tail->tstamp; tap->wr_antenna = (LE_16(head->flags) >> 4) & 0xf; switch (head->rate) { /* CCK rates */ case 10: tap->wr_rate = 2; break; case 20: tap->wr_rate = 4; break; case 55: tap->wr_rate = 11; break; case 110: tap->wr_rate = 22; break; /* OFDM rates */ case 0xd: tap->wr_rate = 12; break; case 0xf: tap->wr_rate = 18; break; case 0x5: tap->wr_rate = 24; break; case 0x7: tap->wr_rate = 36; break; case 0x9: tap->wr_rate = 48; break; case 0xb: tap->wr_rate = 72; break; case 0x1: tap->wr_rate = 96; break; case 0x3: tap->wr_rate = 108; break; /* unknown rate: should not happen */ default: tap->wr_rate = 0; } if (LE_16(head->flags) & 0x4) tap->wr_flags |= IEEE80211_RADIOTAP_F_SHORTPRE; bpf_mtap2(sc->sc_drvbpf, tap, sc->sc_rxtap_len, m); } #endif /* grab a reference to the source node */ wh = (struct ieee80211_frame *)(head + 1); #ifdef DEBUG if (wpi_dbg_flags & WPI_DEBUG_RX) ieee80211_dump_pkt((uint8_t *)wh, len, 0, 0); #endif in = ieee80211_find_rxnode(ic, wh); mp = allocb(len, BPRI_MED); if (mp) { (void) memcpy(mp->b_wptr, wh, len); mp->b_wptr += len; /* send the frame to the 802.11 layer */ (void) ieee80211_input(ic, mp, in, stat->rssi, 0); } else { sc->sc_rx_nobuf++; WPI_DBG((WPI_DEBUG_RX, "wpi_rx_intr(): alloc rx buf failed\n")); } /* release node reference */ ieee80211_free_node(in); } /*ARGSUSED*/ static void wpi_tx_intr(wpi_sc_t *sc, wpi_rx_desc_t *desc, wpi_rx_data_t *data) { ieee80211com_t *ic = &sc->sc_ic; wpi_tx_ring_t *ring = &sc->sc_txq[desc->qid & 0x3]; /* wpi_tx_data_t *txdata = &ring->data[desc->idx]; */ wpi_tx_stat_t *stat = (wpi_tx_stat_t *)(desc + 1); wpi_amrr_t *amrr = (wpi_amrr_t *)ic->ic_bss; WPI_DBG((WPI_DEBUG_TX, "tx done: qid=%d idx=%d retries=%d nkill=%d " "rate=%x duration=%d status=%x\n", desc->qid, desc->idx, stat->ntries, stat->nkill, stat->rate, LE_32(stat->duration), LE_32(stat->status))); amrr->txcnt++; WPI_DBG((WPI_DEBUG_RATECTL, "tx: %d cnt\n", amrr->txcnt)); if (stat->ntries > 0) { amrr->retrycnt++; sc->sc_tx_retries++; WPI_DBG((WPI_DEBUG_RATECTL, "tx: %d retries\n", amrr->retrycnt)); } sc->sc_tx_timer = 0; mutex_enter(&sc->sc_tx_lock); ring->queued--; if (ring->queued < 0) ring->queued = 0; if ((sc->sc_need_reschedule) && (ring->queued <= (ring->count << 3))) { sc->sc_need_reschedule = 0; mutex_exit(&sc->sc_tx_lock); mac_tx_update(ic->ic_mach); mutex_enter(&sc->sc_tx_lock); } mutex_exit(&sc->sc_tx_lock); } static void wpi_cmd_intr(wpi_sc_t *sc, wpi_rx_desc_t *desc) { if ((desc->qid & 7) != 4) { return; /* not a command ack */ } mutex_enter(&sc->sc_glock); sc->sc_flags |= WPI_F_CMD_DONE; cv_signal(&sc->sc_cmd_cv); mutex_exit(&sc->sc_glock); } static uint_t wpi_notif_softintr(caddr_t arg) { wpi_sc_t *sc = (wpi_sc_t *)arg; ieee80211com_t *ic = &sc->sc_ic; wpi_rx_desc_t *desc; wpi_rx_data_t *data; uint32_t hw; mutex_enter(&sc->sc_glock); if (sc->sc_notif_softint_pending != 1) { mutex_exit(&sc->sc_glock); return (DDI_INTR_UNCLAIMED); } mutex_exit(&sc->sc_glock); hw = LE_32(sc->sc_shared->next); while (sc->sc_rxq.cur != hw) { data = &sc->sc_rxq.data[sc->sc_rxq.cur]; desc = (wpi_rx_desc_t *)data->dma_data.mem_va; WPI_DBG((WPI_DEBUG_INTR, "rx notification hw = %d cur = %d " "qid=%x idx=%d flags=%x type=%d len=%d\n", hw, sc->sc_rxq.cur, desc->qid, desc->idx, desc->flags, desc->type, LE_32(desc->len))); if (!(desc->qid & 0x80)) /* reply to a command */ wpi_cmd_intr(sc, desc); switch (desc->type) { case WPI_RX_DONE: /* a 802.11 frame was received */ wpi_rx_intr(sc, desc, data); break; case WPI_TX_DONE: /* a 802.11 frame has been transmitted */ wpi_tx_intr(sc, desc, data); break; case WPI_UC_READY: { wpi_ucode_info_t *uc = (wpi_ucode_info_t *)(desc + 1); /* the microcontroller is ready */ WPI_DBG((WPI_DEBUG_FW, "microcode alive notification version %x " "alive %x\n", LE_32(uc->version), LE_32(uc->valid))); if (LE_32(uc->valid) != 1) { WPI_DBG((WPI_DEBUG_FW, "microcontroller initialization failed\n")); } break; } case WPI_STATE_CHANGED: { uint32_t *status = (uint32_t *)(desc + 1); /* enabled/disabled notification */ WPI_DBG((WPI_DEBUG_RADIO, "state changed to %x\n", LE_32(*status))); if (LE_32(*status) & 1) { /* * the radio button has to be pushed(OFF). It * is considered as a hw error, the * wpi_thread() tries to recover it after the * button is pushed again(ON) */ cmn_err(CE_NOTE, "wpi: Radio transmitter is off\n"); sc->sc_ostate = sc->sc_ic.ic_state; ieee80211_new_state(&sc->sc_ic, IEEE80211_S_INIT, -1); sc->sc_flags |= (WPI_F_HW_ERR_RECOVER | WPI_F_RADIO_OFF); } break; } case WPI_START_SCAN: { wpi_start_scan_t *scan = (wpi_start_scan_t *)(desc + 1); WPI_DBG((WPI_DEBUG_SCAN, "scanning channel %d status %x\n", scan->chan, LE_32(scan->status))); /* fix current channel */ ic->ic_curchan = &ic->ic_sup_channels[scan->chan]; break; } case WPI_STOP_SCAN: WPI_DBG((WPI_DEBUG_SCAN, "scan finished\n")); ieee80211_end_scan(ic); break; } sc->sc_rxq.cur = (sc->sc_rxq.cur + 1) % WPI_RX_RING_COUNT; } /* tell the firmware what we have processed */ hw = (hw == 0) ? WPI_RX_RING_COUNT - 1 : hw - 1; WPI_WRITE(sc, WPI_RX_WIDX, hw & (~7)); mutex_enter(&sc->sc_glock); sc->sc_notif_softint_pending = 0; mutex_exit(&sc->sc_glock); return (DDI_INTR_CLAIMED); } static uint_t wpi_intr(caddr_t arg) { wpi_sc_t *sc = (wpi_sc_t *)arg; uint32_t r, rfh; mutex_enter(&sc->sc_glock); if (sc->sc_flags & WPI_F_SUSPEND) { mutex_exit(&sc->sc_glock); return (DDI_INTR_UNCLAIMED); } r = WPI_READ(sc, WPI_INTR); if (r == 0 || r == 0xffffffff) { mutex_exit(&sc->sc_glock); return (DDI_INTR_UNCLAIMED); } WPI_DBG((WPI_DEBUG_INTR, "interrupt reg %x\n", r)); rfh = WPI_READ(sc, WPI_INTR_STATUS); /* disable interrupts */ WPI_WRITE(sc, WPI_MASK, 0); /* ack interrupts */ WPI_WRITE(sc, WPI_INTR, r); WPI_WRITE(sc, WPI_INTR_STATUS, rfh); if (sc->sc_notif_softint_id == NULL) { mutex_exit(&sc->sc_glock); return (DDI_INTR_CLAIMED); } if (r & (WPI_SW_ERROR | WPI_HW_ERROR)) { WPI_DBG((WPI_DEBUG_FW, "fatal firmware error\n")); mutex_exit(&sc->sc_glock); wpi_stop(sc); sc->sc_ostate = sc->sc_ic.ic_state; ieee80211_new_state(&sc->sc_ic, IEEE80211_S_INIT, -1); sc->sc_flags |= WPI_F_HW_ERR_RECOVER; return (DDI_INTR_CLAIMED); } if ((r & (WPI_RX_INTR | WPI_RX_SWINT)) || (rfh & 0x40070000)) { sc->sc_notif_softint_pending = 1; ddi_trigger_softintr(sc->sc_notif_softint_id); } if (r & WPI_ALIVE_INTR) { /* firmware initialized */ sc->sc_flags |= WPI_F_FW_INIT; cv_signal(&sc->sc_fw_cv); } /* re-enable interrupts */ WPI_WRITE(sc, WPI_MASK, WPI_INTR_MASK); mutex_exit(&sc->sc_glock); return (DDI_INTR_CLAIMED); } static uint8_t wpi_plcp_signal(int rate) { switch (rate) { /* CCK rates (returned values are device-dependent) */ case 2: return (10); case 4: return (20); case 11: return (55); case 22: return (110); /* OFDM rates (cf IEEE Std 802.11a-1999, pp. 14 Table 80) */ /* R1-R4 (ral/ural is R4-R1) */ case 12: return (0xd); case 18: return (0xf); case 24: return (0x5); case 36: return (0x7); case 48: return (0x9); case 72: return (0xb); case 96: return (0x1); case 108: return (0x3); /* unsupported rates (should not get there) */ default: return (0); } } static mblk_t * wpi_m_tx(void *arg, mblk_t *mp) { wpi_sc_t *sc = (wpi_sc_t *)arg; ieee80211com_t *ic = &sc->sc_ic; mblk_t *next; if (sc->sc_flags & WPI_F_SUSPEND) { freemsgchain(mp); return (NULL); } if (ic->ic_state != IEEE80211_S_RUN) { freemsgchain(mp); return (NULL); } while (mp != NULL) { next = mp->b_next; mp->b_next = NULL; if (wpi_send(ic, mp, IEEE80211_FC0_TYPE_DATA) != 0) { mp->b_next = next; break; } mp = next; } return (mp); } /* ARGSUSED */ static int wpi_send(ieee80211com_t *ic, mblk_t *mp, uint8_t type) { wpi_sc_t *sc = (wpi_sc_t *)ic; wpi_tx_ring_t *ring; wpi_tx_desc_t *desc; wpi_tx_data_t *data; wpi_tx_cmd_t *cmd; wpi_cmd_data_t *tx; ieee80211_node_t *in; struct ieee80211_frame *wh; struct ieee80211_key *k; mblk_t *m, *m0; int rate, hdrlen, len, mblen, off, err = WPI_SUCCESS; ring = ((type & IEEE80211_FC0_TYPE_MASK) != IEEE80211_FC0_TYPE_DATA) ? (&sc->sc_txq[0]) : (&sc->sc_txq[1]); data = &ring->data[ring->cur]; desc = data->desc; cmd = data->cmd; bzero(desc, sizeof (*desc)); bzero(cmd, sizeof (*cmd)); mutex_enter(&sc->sc_tx_lock); if (sc->sc_flags & WPI_F_SUSPEND) { mutex_exit(&sc->sc_tx_lock); if ((type & IEEE80211_FC0_TYPE_MASK) != IEEE80211_FC0_TYPE_DATA) { freemsg(mp); } err = ENXIO; goto exit; } if (ring->queued > ring->count - 64) { WPI_DBG((WPI_DEBUG_TX, "wpi_send(): no txbuf\n")); sc->sc_need_reschedule = 1; mutex_exit(&sc->sc_tx_lock); if ((type & IEEE80211_FC0_TYPE_MASK) != IEEE80211_FC0_TYPE_DATA) { freemsg(mp); } sc->sc_tx_nobuf++; err = ENOMEM; goto exit; } mutex_exit(&sc->sc_tx_lock); hdrlen = sizeof (struct ieee80211_frame); m = allocb(msgdsize(mp) + 32, BPRI_MED); if (m == NULL) { /* can not alloc buf, drop this package */ cmn_err(CE_WARN, "wpi_send(): failed to allocate msgbuf\n"); freemsg(mp); err = WPI_SUCCESS; goto exit; } for (off = 0, m0 = mp; m0 != NULL; m0 = m0->b_cont) { mblen = MBLKL(m0); (void) memcpy(m->b_rptr + off, m0->b_rptr, mblen); off += mblen; } m->b_wptr += off; freemsg(mp); wh = (struct ieee80211_frame *)m->b_rptr; in = ieee80211_find_txnode(ic, wh->i_addr1); if (in == NULL) { cmn_err(CE_WARN, "wpi_send(): failed to find tx node\n"); freemsg(m); sc->sc_tx_err++; err = WPI_SUCCESS; goto exit; } (void) ieee80211_encap(ic, m, in); cmd->code = WPI_CMD_TX_DATA; cmd->flags = 0; cmd->qid = ring->qid; cmd->idx = ring->cur; tx = (wpi_cmd_data_t *)cmd->data; tx->flags = 0; if (!IEEE80211_IS_MULTICAST(wh->i_addr1)) { tx->flags |= LE_32(WPI_TX_NEED_ACK); } else { tx->flags &= ~(LE_32(WPI_TX_NEED_ACK)); } if (wh->i_fc[1] & IEEE80211_FC1_WEP) { k = ieee80211_crypto_encap(ic, m); if (k == NULL) { freemsg(m); sc->sc_tx_err++; err = WPI_SUCCESS; goto exit; } if (k->wk_cipher->ic_cipher == IEEE80211_CIPHER_AES_CCM) { tx->security = 2; /* for CCMP */ tx->flags |= LE_32(WPI_TX_NEED_ACK); (void) memcpy(&tx->key, k->wk_key, k->wk_keylen); } /* packet header may have moved, reset our local pointer */ wh = (struct ieee80211_frame *)m->b_rptr; } len = msgdsize(m); #ifdef DEBUG if (wpi_dbg_flags & WPI_DEBUG_TX) ieee80211_dump_pkt((uint8_t *)wh, hdrlen, 0, 0); #endif /* pickup a rate */ if ((wh->i_fc[0] & IEEE80211_FC0_TYPE_MASK) == IEEE80211_FC0_TYPE_MGT) { /* mgmt frames are sent at the lowest available bit-rate */ rate = 2; } else { if (ic->ic_fixed_rate != IEEE80211_FIXED_RATE_NONE) { rate = ic->ic_fixed_rate; } else rate = in->in_rates.ir_rates[in->in_txrate]; } rate &= IEEE80211_RATE_VAL; WPI_DBG((WPI_DEBUG_RATECTL, "tx rate[%d of %d] = %x", in->in_txrate, in->in_rates.ir_nrates, rate)); #ifdef WPI_BPF #ifndef WPI_CURRENT if (sc->sc_drvbpf != NULL) { #else if (bpf_peers_present(sc->sc_drvbpf)) { #endif struct wpi_tx_radiotap_header *tap = &sc->sc_txtap; tap->wt_flags = 0; tap->wt_chan_freq = LE_16(ic->ic_curchan->ic_freq); tap->wt_chan_flags = LE_16(ic->ic_curchan->ic_flags); tap->wt_rate = rate; if (wh->i_fc[1] & IEEE80211_FC1_WEP) tap->wt_flags |= IEEE80211_RADIOTAP_F_WEP; bpf_mtap2(sc->sc_drvbpf, tap, sc->sc_txtap_len, m0); } #endif tx->flags |= (LE_32(WPI_TX_AUTO_SEQ)); tx->flags |= LE_32(WPI_TX_BT_DISABLE | WPI_TX_CALIBRATION); /* retrieve destination node's id */ tx->id = IEEE80211_IS_MULTICAST(wh->i_addr1) ? WPI_ID_BROADCAST : WPI_ID_BSS; if ((wh->i_fc[0] & IEEE80211_FC0_TYPE_MASK) == IEEE80211_FC0_TYPE_MGT) { /* tell h/w to set timestamp in probe responses */ if ((wh->i_fc[0] & IEEE80211_FC0_SUBTYPE_MASK) == IEEE80211_FC0_SUBTYPE_PROBE_RESP) tx->flags |= LE_32(WPI_TX_INSERT_TSTAMP); if (((wh->i_fc[0] & IEEE80211_FC0_SUBTYPE_MASK) == IEEE80211_FC0_SUBTYPE_ASSOC_REQ) || ((wh->i_fc[0] & IEEE80211_FC0_SUBTYPE_MASK) == IEEE80211_FC0_SUBTYPE_REASSOC_REQ)) tx->timeout = 3; else tx->timeout = 2; } else tx->timeout = 0; tx->rate = wpi_plcp_signal(rate); /* be very persistant at sending frames out */ tx->rts_ntries = 7; tx->data_ntries = 15; tx->cck_mask = 0x0f; tx->ofdm_mask = 0xff; tx->lifetime = LE_32(0xffffffff); tx->len = LE_16(len); /* save and trim IEEE802.11 header */ (void) memcpy(tx + 1, m->b_rptr, hdrlen); m->b_rptr += hdrlen; (void) memcpy(data->dma_data.mem_va, m->b_rptr, len - hdrlen); WPI_DBG((WPI_DEBUG_TX, "sending data: qid=%d idx=%d len=%d", ring->qid, ring->cur, len)); /* first scatter/gather segment is used by the tx data command */ desc->flags = LE_32(WPI_PAD32(len) << 28 | (2) << 24); desc->segs[0].addr = LE_32(data->paddr_cmd); desc->segs[0].len = LE_32( roundup(4 + sizeof (wpi_cmd_data_t) + hdrlen, 4)); desc->segs[1].addr = LE_32(data->dma_data.cookie.dmac_address); desc->segs[1].len = LE_32(len - hdrlen); WPI_DMA_SYNC(data->dma_data, DDI_DMA_SYNC_FORDEV); WPI_DMA_SYNC(ring->dma_desc, DDI_DMA_SYNC_FORDEV); mutex_enter(&sc->sc_tx_lock); ring->queued++; mutex_exit(&sc->sc_tx_lock); /* kick ring */ ring->cur = (ring->cur + 1) % WPI_TX_RING_COUNT; WPI_WRITE(sc, WPI_TX_WIDX, ring->qid << 8 | ring->cur); freemsg(m); /* release node reference */ ieee80211_free_node(in); ic->ic_stats.is_tx_bytes += len; ic->ic_stats.is_tx_frags++; if (sc->sc_tx_timer == 0) sc->sc_tx_timer = 5; exit: return (err); } static void wpi_m_ioctl(void* arg, queue_t *wq, mblk_t *mp) { wpi_sc_t *sc = (wpi_sc_t *)arg; ieee80211com_t *ic = &sc->sc_ic; int err; err = ieee80211_ioctl(ic, wq, mp); if (err == ENETRESET) { /* * This is special for the hidden AP connection. * In any case, we should make sure only one 'scan' * in the driver for a 'connect' CLI command. So * when connecting to a hidden AP, the scan is just * sent out to the air when we know the desired * essid of the AP we want to connect. */ if (ic->ic_des_esslen) { (void) ieee80211_new_state(ic, IEEE80211_S_SCAN, -1); } } } /*ARGSUSED*/ static int wpi_m_stat(void *arg, uint_t stat, uint64_t *val) { wpi_sc_t *sc = (wpi_sc_t *)arg; ieee80211com_t *ic = &sc->sc_ic; ieee80211_node_t *in = ic->ic_bss; struct ieee80211_rateset *rs = &in->in_rates; mutex_enter(&sc->sc_glock); switch (stat) { case MAC_STAT_IFSPEED: *val = ((ic->ic_fixed_rate == IEEE80211_FIXED_RATE_NONE) ? (rs->ir_rates[in->in_txrate] & IEEE80211_RATE_VAL) : ic->ic_fixed_rate) / 2 * 1000000; break; case MAC_STAT_NOXMTBUF: *val = sc->sc_tx_nobuf; break; case MAC_STAT_NORCVBUF: *val = sc->sc_rx_nobuf; break; case MAC_STAT_IERRORS: *val = sc->sc_rx_err; break; case MAC_STAT_RBYTES: *val = ic->ic_stats.is_rx_bytes; break; case MAC_STAT_IPACKETS: *val = ic->ic_stats.is_rx_frags; break; case MAC_STAT_OBYTES: *val = ic->ic_stats.is_tx_bytes; break; case MAC_STAT_OPACKETS: *val = ic->ic_stats.is_tx_frags; break; case MAC_STAT_OERRORS: case WIFI_STAT_TX_FAILED: *val = sc->sc_tx_err; break; case WIFI_STAT_TX_RETRANS: *val = sc->sc_tx_retries; break; case WIFI_STAT_FCS_ERRORS: case WIFI_STAT_WEP_ERRORS: case WIFI_STAT_TX_FRAGS: case WIFI_STAT_MCAST_TX: case WIFI_STAT_RTS_SUCCESS: case WIFI_STAT_RTS_FAILURE: case WIFI_STAT_ACK_FAILURE: case WIFI_STAT_RX_FRAGS: case WIFI_STAT_MCAST_RX: case WIFI_STAT_RX_DUPS: mutex_exit(&sc->sc_glock); return (ieee80211_stat(ic, stat, val)); default: mutex_exit(&sc->sc_glock); return (ENOTSUP); } mutex_exit(&sc->sc_glock); return (WPI_SUCCESS); } static int wpi_m_start(void *arg) { wpi_sc_t *sc = (wpi_sc_t *)arg; ieee80211com_t *ic = &sc->sc_ic; int err; err = wpi_init(sc); if (err != WPI_SUCCESS) { wpi_stop(sc); DELAY(1000000); err = wpi_init(sc); } if (err) { /* * The hw init err(eg. RF is OFF). Return Success to make * the 'plumb' succeed. The wpi_thread() tries to re-init * background. */ mutex_enter(&sc->sc_glock); sc->sc_flags |= WPI_F_HW_ERR_RECOVER; mutex_exit(&sc->sc_glock); return (WPI_SUCCESS); } ieee80211_new_state(ic, IEEE80211_S_INIT, -1); mutex_enter(&sc->sc_glock); sc->sc_flags |= WPI_F_RUNNING; mutex_exit(&sc->sc_glock); return (WPI_SUCCESS); } static void wpi_m_stop(void *arg) { wpi_sc_t *sc = (wpi_sc_t *)arg; ieee80211com_t *ic = &sc->sc_ic; wpi_stop(sc); ieee80211_new_state(ic, IEEE80211_S_INIT, -1); mutex_enter(&sc->sc_mt_lock); sc->sc_flags &= ~WPI_F_HW_ERR_RECOVER; sc->sc_flags &= ~WPI_F_RATE_AUTO_CTL; mutex_exit(&sc->sc_mt_lock); mutex_enter(&sc->sc_glock); sc->sc_flags &= ~WPI_F_RUNNING; mutex_exit(&sc->sc_glock); } /*ARGSUSED*/ static int wpi_m_unicst(void *arg, const uint8_t *macaddr) { wpi_sc_t *sc = (wpi_sc_t *)arg; ieee80211com_t *ic = &sc->sc_ic; int err; if (!IEEE80211_ADDR_EQ(ic->ic_macaddr, macaddr)) { IEEE80211_ADDR_COPY(ic->ic_macaddr, macaddr); mutex_enter(&sc->sc_glock); err = wpi_config(sc); mutex_exit(&sc->sc_glock); if (err != WPI_SUCCESS) { cmn_err(CE_WARN, "wpi_m_unicst(): " "failed to configure device\n"); goto fail; } } return (WPI_SUCCESS); fail: return (err); } /*ARGSUSED*/ static int wpi_m_multicst(void *arg, boolean_t add, const uint8_t *m) { return (WPI_SUCCESS); } /*ARGSUSED*/ static int wpi_m_promisc(void *arg, boolean_t on) { return (WPI_SUCCESS); } static void wpi_thread(wpi_sc_t *sc) { ieee80211com_t *ic = &sc->sc_ic; clock_t clk; int times = 0, err, n = 0, timeout = 0; uint32_t tmp; mutex_enter(&sc->sc_mt_lock); while (sc->sc_mf_thread_switch) { tmp = WPI_READ(sc, WPI_GPIO_CTL); if (tmp & WPI_GPIO_HW_RF_KILL) { sc->sc_flags &= ~WPI_F_RADIO_OFF; } else { sc->sc_flags |= WPI_F_RADIO_OFF; } /* * If in SUSPEND or the RF is OFF, do nothing */ if ((sc->sc_flags & WPI_F_SUSPEND) || (sc->sc_flags & WPI_F_RADIO_OFF)) { mutex_exit(&sc->sc_mt_lock); delay(drv_usectohz(100000)); mutex_enter(&sc->sc_mt_lock); continue; } /* * recovery fatal error */ if (ic->ic_mach && (sc->sc_flags & WPI_F_HW_ERR_RECOVER)) { WPI_DBG((WPI_DEBUG_FW, "wpi_thread(): " "try to recover fatal hw error: %d\n", times++)); wpi_stop(sc); ieee80211_new_state(ic, IEEE80211_S_INIT, -1); mutex_exit(&sc->sc_mt_lock); delay(drv_usectohz(2000000)); mutex_enter(&sc->sc_mt_lock); err = wpi_init(sc); if (err != WPI_SUCCESS) { n++; if (n < 3) continue; } n = 0; if (!err) sc->sc_flags |= WPI_F_RUNNING; sc->sc_flags &= ~WPI_F_HW_ERR_RECOVER; mutex_exit(&sc->sc_mt_lock); delay(drv_usectohz(2000000)); if (sc->sc_ostate != IEEE80211_S_INIT) ieee80211_new_state(ic, IEEE80211_S_SCAN, 0); mutex_enter(&sc->sc_mt_lock); } /* * rate ctl */ if (ic->ic_mach && (sc->sc_flags & WPI_F_RATE_AUTO_CTL)) { clk = ddi_get_lbolt(); if (clk > sc->sc_clk + drv_usectohz(500000)) { wpi_amrr_timeout(sc); } } mutex_exit(&sc->sc_mt_lock); delay(drv_usectohz(100000)); mutex_enter(&sc->sc_mt_lock); if (sc->sc_tx_timer) { timeout++; if (timeout == 10) { sc->sc_tx_timer--; if (sc->sc_tx_timer == 0) { sc->sc_flags |= WPI_F_HW_ERR_RECOVER; sc->sc_ostate = IEEE80211_S_RUN; } timeout = 0; } } } sc->sc_mf_thread = NULL; cv_signal(&sc->sc_mt_cv); mutex_exit(&sc->sc_mt_lock); } /* * Extract various information from EEPROM. */ static void wpi_read_eeprom(wpi_sc_t *sc) { ieee80211com_t *ic = &sc->sc_ic; uint16_t val; int i; /* read MAC address */ val = wpi_read_prom_word(sc, WPI_EEPROM_MAC + 0); ic->ic_macaddr[0] = val & 0xff; ic->ic_macaddr[1] = val >> 8; val = wpi_read_prom_word(sc, WPI_EEPROM_MAC + 1); ic->ic_macaddr[2] = val & 0xff; ic->ic_macaddr[3] = val >> 8; val = wpi_read_prom_word(sc, WPI_EEPROM_MAC + 2); ic->ic_macaddr[4] = val & 0xff; ic->ic_macaddr[5] = val >> 8; WPI_DBG((WPI_DEBUG_EEPROM, "mac:%2x:%2x:%2x:%2x:%2x:%2x\n", ic->ic_macaddr[0], ic->ic_macaddr[1], ic->ic_macaddr[2], ic->ic_macaddr[3], ic->ic_macaddr[4], ic->ic_macaddr[5])); /* read power settings for 2.4GHz channels */ for (i = 0; i < 14; i++) { sc->sc_pwr1[i] = wpi_read_prom_word(sc, WPI_EEPROM_PWR1 + i); sc->sc_pwr2[i] = wpi_read_prom_word(sc, WPI_EEPROM_PWR2 + i); WPI_DBG((WPI_DEBUG_EEPROM, "channel %d pwr1 0x%04x pwr2 0x%04x\n", i + 1, sc->sc_pwr1[i], sc->sc_pwr2[i])); } } /* * Send a command to the firmware. */ static int wpi_cmd(wpi_sc_t *sc, int code, const void *buf, int size, int async) { wpi_tx_ring_t *ring = &sc->sc_cmdq; wpi_tx_desc_t *desc; wpi_tx_cmd_t *cmd; ASSERT(size <= sizeof (cmd->data)); ASSERT(mutex_owned(&sc->sc_glock)); WPI_DBG((WPI_DEBUG_CMD, "wpi_cmd() # code[%d]", code)); desc = ring->data[ring->cur].desc; cmd = ring->data[ring->cur].cmd; cmd->code = (uint8_t)code; cmd->flags = 0; cmd->qid = ring->qid; cmd->idx = ring->cur; (void) memcpy(cmd->data, buf, size); desc->flags = LE_32(WPI_PAD32(size) << 28 | 1 << 24); desc->segs[0].addr = ring->data[ring->cur].paddr_cmd; desc->segs[0].len = 4 + size; /* kick cmd ring */ ring->cur = (ring->cur + 1) % WPI_CMD_RING_COUNT; WPI_WRITE(sc, WPI_TX_WIDX, ring->qid << 8 | ring->cur); if (async) return (WPI_SUCCESS); else { clock_t clk; sc->sc_flags &= ~WPI_F_CMD_DONE; clk = ddi_get_lbolt() + drv_usectohz(2000000); while (!(sc->sc_flags & WPI_F_CMD_DONE)) { if (cv_timedwait(&sc->sc_cmd_cv, &sc->sc_glock, clk) < 0) break; } if (sc->sc_flags & WPI_F_CMD_DONE) return (WPI_SUCCESS); else return (WPI_FAIL); } } /* * Configure h/w multi-rate retries. */ static int wpi_mrr_setup(wpi_sc_t *sc) { wpi_mrr_setup_t mrr; int i, err; /* CCK rates (not used with 802.11a) */ for (i = WPI_CCK1; i <= WPI_CCK11; i++) { mrr.rates[i].flags = 0; mrr.rates[i].signal = wpi_ridx_to_signal[i]; /* fallback to the immediate lower CCK rate (if any) */ mrr.rates[i].next = (i == WPI_CCK1) ? WPI_CCK1 : i - 1; /* try one time at this rate before falling back to "next" */ mrr.rates[i].ntries = 1; } /* OFDM rates (not used with 802.11b) */ for (i = WPI_OFDM6; i <= WPI_OFDM54; i++) { mrr.rates[i].flags = 0; mrr.rates[i].signal = wpi_ridx_to_signal[i]; /* fallback to the immediate lower OFDM rate (if any) */ mrr.rates[i].next = (i == WPI_OFDM6) ? WPI_OFDM6 : i - 1; /* try one time at this rate before falling back to "next" */ mrr.rates[i].ntries = 1; } /* setup MRR for control frames */ mrr.which = LE_32(WPI_MRR_CTL); err = wpi_cmd(sc, WPI_CMD_MRR_SETUP, &mrr, sizeof (mrr), 1); if (err != WPI_SUCCESS) { WPI_DBG((WPI_DEBUG_MRR, "could not setup MRR for control frames\n")); return (err); } /* setup MRR for data frames */ mrr.which = LE_32(WPI_MRR_DATA); err = wpi_cmd(sc, WPI_CMD_MRR_SETUP, &mrr, sizeof (mrr), 1); if (err != WPI_SUCCESS) { WPI_DBG((WPI_DEBUG_MRR, "could not setup MRR for data frames\n")); return (err); } return (WPI_SUCCESS); } static void wpi_set_led(wpi_sc_t *sc, uint8_t which, uint8_t off, uint8_t on) { wpi_cmd_led_t led; led.which = which; led.unit = LE_32(100000); /* on/off in unit of 100ms */ led.off = off; led.on = on; (void) wpi_cmd(sc, WPI_CMD_SET_LED, &led, sizeof (led), 1); } static int wpi_auth(wpi_sc_t *sc) { ieee80211com_t *ic = &sc->sc_ic; ieee80211_node_t *in = ic->ic_bss; wpi_node_t node; int err; /* update adapter's configuration */ IEEE80211_ADDR_COPY(sc->sc_config.bssid, in->in_bssid); sc->sc_config.chan = ieee80211_chan2ieee(ic, in->in_chan); if (ic->ic_curmode == IEEE80211_MODE_11B) { sc->sc_config.cck_mask = 0x03; sc->sc_config.ofdm_mask = 0; } else if ((in->in_chan != IEEE80211_CHAN_ANYC) && (IEEE80211_IS_CHAN_5GHZ(in->in_chan))) { sc->sc_config.cck_mask = 0; sc->sc_config.ofdm_mask = 0x15; } else { /* assume 802.11b/g */ sc->sc_config.cck_mask = 0x0f; sc->sc_config.ofdm_mask = 0xff; } WPI_DBG((WPI_DEBUG_80211, "config chan %d flags %x cck %x ofdm %x" " bssid:%02x:%02x:%02x:%02x:%02x:%2x\n", sc->sc_config.chan, sc->sc_config.flags, sc->sc_config.cck_mask, sc->sc_config.ofdm_mask, sc->sc_config.bssid[0], sc->sc_config.bssid[1], sc->sc_config.bssid[2], sc->sc_config.bssid[3], sc->sc_config.bssid[4], sc->sc_config.bssid[5])); err = wpi_cmd(sc, WPI_CMD_CONFIGURE, &sc->sc_config, sizeof (wpi_config_t), 1); if (err != WPI_SUCCESS) { cmn_err(CE_WARN, "wpi_auth(): failed to configurate chan%d\n", sc->sc_config.chan); return (err); } /* add default node */ (void) memset(&node, 0, sizeof (node)); IEEE80211_ADDR_COPY(node.bssid, in->in_bssid); node.id = WPI_ID_BSS; node.rate = wpi_plcp_signal(2); err = wpi_cmd(sc, WPI_CMD_ADD_NODE, &node, sizeof (node), 1); if (err != WPI_SUCCESS) { cmn_err(CE_WARN, "wpi_auth(): failed to add BSS node\n"); return (err); } err = wpi_mrr_setup(sc); if (err != WPI_SUCCESS) { cmn_err(CE_WARN, "wpi_auth(): failed to setup MRR\n"); return (err); } return (WPI_SUCCESS); } /* * Send a scan request to the firmware. */ static int wpi_scan(wpi_sc_t *sc) { ieee80211com_t *ic = &sc->sc_ic; wpi_tx_ring_t *ring = &sc->sc_cmdq; wpi_tx_desc_t *desc; wpi_tx_data_t *data; wpi_tx_cmd_t *cmd; wpi_scan_hdr_t *hdr; wpi_scan_chan_t *chan; struct ieee80211_frame *wh; ieee80211_node_t *in = ic->ic_bss; struct ieee80211_rateset *rs; enum ieee80211_phymode mode; uint8_t *frm; int i, pktlen, nrates; data = &ring->data[ring->cur]; desc = data->desc; cmd = (wpi_tx_cmd_t *)data->dma_data.mem_va; cmd->code = WPI_CMD_SCAN; cmd->flags = 0; cmd->qid = ring->qid; cmd->idx = ring->cur; hdr = (wpi_scan_hdr_t *)cmd->data; (void) memset(hdr, 0, sizeof (wpi_scan_hdr_t)); hdr->first = 1; hdr->nchan = 14; hdr->len = hdr->nchan * sizeof (wpi_scan_chan_t); hdr->quiet = LE_16(5); hdr->threshold = LE_16(1); hdr->filter = LE_32(5); hdr->rate = wpi_plcp_signal(2); hdr->id = WPI_ID_BROADCAST; hdr->mask = LE_32(0xffffffff); hdr->esslen = ic->ic_des_esslen; if (ic->ic_des_esslen) bcopy(ic->ic_des_essid, hdr->essid, ic->ic_des_esslen); else bzero(hdr->essid, sizeof (hdr->essid)); /* * Build a probe request frame. Most of the following code is a * copy & paste of what is done in net80211. Unfortunately, the * functions to add IEs are static and thus can't be reused here. */ wh = (struct ieee80211_frame *)(hdr + 1); wh->i_fc[0] = IEEE80211_FC0_VERSION_0 | IEEE80211_FC0_TYPE_MGT | IEEE80211_FC0_SUBTYPE_PROBE_REQ; wh->i_fc[1] = IEEE80211_FC1_DIR_NODS; (void) memset(wh->i_addr1, 0xff, 6); IEEE80211_ADDR_COPY(wh->i_addr2, ic->ic_macaddr); (void) memset(wh->i_addr3, 0xff, 6); *(uint16_t *)&wh->i_dur[0] = 0; /* filled by h/w */ *(uint16_t *)&wh->i_seq[0] = 0; /* filled by h/w */ frm = (uint8_t *)(wh + 1); /* add essid IE */ *frm++ = IEEE80211_ELEMID_SSID; *frm++ = in->in_esslen; (void) memcpy(frm, in->in_essid, in->in_esslen); frm += in->in_esslen; mode = ieee80211_chan2mode(ic, ic->ic_curchan); rs = &ic->ic_sup_rates[mode]; /* add supported rates IE */ *frm++ = IEEE80211_ELEMID_RATES; nrates = rs->ir_nrates; if (nrates > IEEE80211_RATE_SIZE) nrates = IEEE80211_RATE_SIZE; *frm++ = (uint8_t)nrates; (void) memcpy(frm, rs->ir_rates, nrates); frm += nrates; /* add supported xrates IE */ if (rs->ir_nrates > IEEE80211_RATE_SIZE) { nrates = rs->ir_nrates - IEEE80211_RATE_SIZE; *frm++ = IEEE80211_ELEMID_XRATES; *frm++ = (uint8_t)nrates; (void) memcpy(frm, rs->ir_rates + IEEE80211_RATE_SIZE, nrates); frm += nrates; } /* add optionnal IE (usually an RSN IE) */ if (ic->ic_opt_ie != NULL) { (void) memcpy(frm, ic->ic_opt_ie, ic->ic_opt_ie_len); frm += ic->ic_opt_ie_len; } /* setup length of probe request */ hdr->pbrlen = LE_16((uintptr_t)frm - (uintptr_t)wh); /* align on a 4-byte boundary */ chan = (wpi_scan_chan_t *)frm; for (i = 1; i <= hdr->nchan; i++, chan++) { chan->flags = 3; chan->chan = (uint8_t)i; chan->magic = LE_16(0x62ab); chan->active = LE_16(20); chan->passive = LE_16(120); frm += sizeof (wpi_scan_chan_t); } pktlen = (uintptr_t)frm - (uintptr_t)cmd; desc->flags = LE_32(WPI_PAD32(pktlen) << 28 | 1 << 24); desc->segs[0].addr = LE_32(data->dma_data.cookie.dmac_address); desc->segs[0].len = LE_32(pktlen); WPI_DMA_SYNC(data->dma_data, DDI_DMA_SYNC_FORDEV); WPI_DMA_SYNC(ring->dma_desc, DDI_DMA_SYNC_FORDEV); /* kick cmd ring */ ring->cur = (ring->cur + 1) % WPI_CMD_RING_COUNT; WPI_WRITE(sc, WPI_TX_WIDX, ring->qid << 8 | ring->cur); return (WPI_SUCCESS); /* will be notified async. of failure/success */ } static int wpi_config(wpi_sc_t *sc) { ieee80211com_t *ic = &sc->sc_ic; wpi_txpower_t txpower; wpi_power_t power; #ifdef WPI_BLUE_COEXISTENCE wpi_bluetooth_t bluetooth; #endif wpi_node_t node; int err; /* Intel's binary only daemon is a joke.. */ /* set Tx power for 2.4GHz channels (values read from EEPROM) */ (void) memset(&txpower, 0, sizeof (txpower)); (void) memcpy(txpower.pwr1, sc->sc_pwr1, 14 * sizeof (uint16_t)); (void) memcpy(txpower.pwr2, sc->sc_pwr2, 14 * sizeof (uint16_t)); err = wpi_cmd(sc, WPI_CMD_TXPOWER, &txpower, sizeof (txpower), 0); if (err != WPI_SUCCESS) { cmn_err(CE_WARN, "wpi_config(): failed to set txpower\n"); return (err); } /* set power mode */ (void) memset(&power, 0, sizeof (power)); power.flags = LE_32(0x8); err = wpi_cmd(sc, WPI_CMD_SET_POWER_MODE, &power, sizeof (power), 0); if (err != WPI_SUCCESS) { cmn_err(CE_WARN, "wpi_config(): failed to set power mode\n"); return (err); } #ifdef WPI_BLUE_COEXISTENCE /* configure bluetooth coexistence */ (void) memset(&bluetooth, 0, sizeof (bluetooth)); bluetooth.flags = 3; bluetooth.lead = 0xaa; bluetooth.kill = 1; err = wpi_cmd(sc, WPI_CMD_BLUETOOTH, &bluetooth, sizeof (bluetooth), 0); if (err != WPI_SUCCESS) { cmn_err(CE_WARN, "wpi_config(): " "failed to configurate bluetooth coexistence\n"); return (err); } #endif /* configure adapter */ (void) memset(&sc->sc_config, 0, sizeof (wpi_config_t)); IEEE80211_ADDR_COPY(sc->sc_config.myaddr, ic->ic_macaddr); sc->sc_config.chan = ieee80211_chan2ieee(ic, ic->ic_curchan); sc->sc_config.flags = LE_32(WPI_CONFIG_TSF | WPI_CONFIG_AUTO | WPI_CONFIG_24GHZ); sc->sc_config.filter = 0; switch (ic->ic_opmode) { case IEEE80211_M_STA: sc->sc_config.mode = WPI_MODE_STA; sc->sc_config.filter |= LE_32(WPI_FILTER_MULTICAST); break; case IEEE80211_M_IBSS: case IEEE80211_M_AHDEMO: sc->sc_config.mode = WPI_MODE_IBSS; break; case IEEE80211_M_HOSTAP: sc->sc_config.mode = WPI_MODE_HOSTAP; break; case IEEE80211_M_MONITOR: sc->sc_config.mode = WPI_MODE_MONITOR; sc->sc_config.filter |= LE_32(WPI_FILTER_MULTICAST | WPI_FILTER_CTL | WPI_FILTER_PROMISC); break; } sc->sc_config.cck_mask = 0x0f; /* not yet negotiated */ sc->sc_config.ofdm_mask = 0xff; /* not yet negotiated */ err = wpi_cmd(sc, WPI_CMD_CONFIGURE, &sc->sc_config, sizeof (wpi_config_t), 0); if (err != WPI_SUCCESS) { cmn_err(CE_WARN, "wpi_config(): " "failed to set configure command\n"); return (err); } /* add broadcast node */ (void) memset(&node, 0, sizeof (node)); (void) memset(node.bssid, 0xff, 6); node.id = WPI_ID_BROADCAST; node.rate = wpi_plcp_signal(2); err = wpi_cmd(sc, WPI_CMD_ADD_NODE, &node, sizeof (node), 0); if (err != WPI_SUCCESS) { cmn_err(CE_WARN, "wpi_config(): " "failed to add broadcast node\n"); return (err); } return (WPI_SUCCESS); } static void wpi_stop_master(wpi_sc_t *sc) { uint32_t tmp; int ntries; tmp = WPI_READ(sc, WPI_RESET); WPI_WRITE(sc, WPI_RESET, tmp | WPI_STOP_MASTER); tmp = WPI_READ(sc, WPI_GPIO_CTL); if ((tmp & WPI_GPIO_PWR_STATUS) == WPI_GPIO_PWR_SLEEP) return; /* already asleep */ for (ntries = 0; ntries < 2000; ntries++) { if (WPI_READ(sc, WPI_RESET) & WPI_MASTER_DISABLED) break; DELAY(1000); } if (ntries == 2000) WPI_DBG((WPI_DEBUG_HW, "timeout waiting for master\n")); } static int wpi_power_up(wpi_sc_t *sc) { uint32_t tmp; int ntries; wpi_mem_lock(sc); tmp = wpi_mem_read(sc, WPI_MEM_POWER); wpi_mem_write(sc, WPI_MEM_POWER, tmp & ~0x03000000); wpi_mem_unlock(sc); for (ntries = 0; ntries < 5000; ntries++) { if (WPI_READ(sc, WPI_GPIO_STATUS) & WPI_POWERED) break; DELAY(10); } if (ntries == 5000) { cmn_err(CE_WARN, "wpi_power_up(): timeout waiting for NIC to power up\n"); return (ETIMEDOUT); } return (WPI_SUCCESS); } static int wpi_reset(wpi_sc_t *sc) { uint32_t tmp; int ntries; /* clear any pending interrupts */ WPI_WRITE(sc, WPI_INTR, 0xffffffff); tmp = WPI_READ(sc, WPI_PLL_CTL); WPI_WRITE(sc, WPI_PLL_CTL, tmp | WPI_PLL_INIT); tmp = WPI_READ(sc, WPI_CHICKEN); WPI_WRITE(sc, WPI_CHICKEN, tmp | WPI_CHICKEN_RXNOLOS); tmp = WPI_READ(sc, WPI_GPIO_CTL); WPI_WRITE(sc, WPI_GPIO_CTL, tmp | WPI_GPIO_INIT); /* wait for clock stabilization */ for (ntries = 0; ntries < 1000; ntries++) { if (WPI_READ(sc, WPI_GPIO_CTL) & WPI_GPIO_CLOCK) break; DELAY(10); } if (ntries == 1000) { cmn_err(CE_WARN, "wpi_reset(): timeout waiting for clock stabilization\n"); return (ETIMEDOUT); } /* initialize EEPROM */ tmp = WPI_READ(sc, WPI_EEPROM_STATUS); if ((tmp & WPI_EEPROM_VERSION) == 0) { cmn_err(CE_WARN, "wpi_reset(): EEPROM not found\n"); return (EIO); } WPI_WRITE(sc, WPI_EEPROM_STATUS, tmp & ~WPI_EEPROM_LOCKED); return (WPI_SUCCESS); } static void wpi_hw_config(wpi_sc_t *sc) { uint16_t val; uint32_t hw; /* voodoo from the Linux "driver".. */ hw = WPI_READ(sc, WPI_HWCONFIG); if ((sc->sc_rev & 0xc0) == 0x40) hw |= WPI_HW_ALM_MB; else if (!(sc->sc_rev & 0x80)) hw |= WPI_HW_ALM_MM; val = wpi_read_prom_word(sc, WPI_EEPROM_CAPABILITIES); if ((val & 0xff) == 0x80) hw |= WPI_HW_SKU_MRC; val = wpi_read_prom_word(sc, WPI_EEPROM_REVISION); hw &= ~WPI_HW_REV_D; if ((val & 0xf0) == 0xd0) hw |= WPI_HW_REV_D; val = wpi_read_prom_word(sc, WPI_EEPROM_TYPE); if ((val & 0xff) > 1) hw |= WPI_HW_TYPE_B; WPI_DBG((WPI_DEBUG_HW, "setting h/w config %x\n", hw)); WPI_WRITE(sc, WPI_HWCONFIG, hw); } static int wpi_init(wpi_sc_t *sc) { uint32_t tmp; int qid, ntries, err; clock_t clk; mutex_enter(&sc->sc_glock); sc->sc_flags &= ~WPI_F_FW_INIT; (void) wpi_reset(sc); wpi_mem_lock(sc); wpi_mem_write(sc, WPI_MEM_CLOCK1, 0xa00); DELAY(20); tmp = wpi_mem_read(sc, WPI_MEM_PCIDEV); wpi_mem_write(sc, WPI_MEM_PCIDEV, tmp | 0x800); wpi_mem_unlock(sc); (void) wpi_power_up(sc); wpi_hw_config(sc); tmp = WPI_READ(sc, WPI_GPIO_CTL); if (!(tmp & WPI_GPIO_HW_RF_KILL)) { cmn_err(CE_WARN, "wpi_init(): Radio transmitter is off\n"); goto fail1; } /* init Rx ring */ wpi_mem_lock(sc); WPI_WRITE(sc, WPI_RX_BASE, sc->sc_rxq.dma_desc.cookie.dmac_address); WPI_WRITE(sc, WPI_RX_RIDX_PTR, (uint32_t)(sc->sc_dma_sh.cookie.dmac_address + offsetof(wpi_shared_t, next))); WPI_WRITE(sc, WPI_RX_WIDX, (WPI_RX_RING_COUNT - 1) & (~7)); WPI_WRITE(sc, WPI_RX_CONFIG, 0xa9601010); wpi_mem_unlock(sc); /* init Tx rings */ wpi_mem_lock(sc); wpi_mem_write(sc, WPI_MEM_MODE, 2); /* bypass mode */ wpi_mem_write(sc, WPI_MEM_RA, 1); /* enable RA0 */ wpi_mem_write(sc, WPI_MEM_TXCFG, 0x3f); /* enable all 6 Tx rings */ wpi_mem_write(sc, WPI_MEM_BYPASS1, 0x10000); wpi_mem_write(sc, WPI_MEM_BYPASS2, 0x30002); wpi_mem_write(sc, WPI_MEM_MAGIC4, 4); wpi_mem_write(sc, WPI_MEM_MAGIC5, 5); WPI_WRITE(sc, WPI_TX_BASE_PTR, sc->sc_dma_sh.cookie.dmac_address); WPI_WRITE(sc, WPI_MSG_CONFIG, 0xffff05a5); for (qid = 0; qid < 6; qid++) { WPI_WRITE(sc, WPI_TX_CTL(qid), 0); WPI_WRITE(sc, WPI_TX_BASE(qid), 0); WPI_WRITE(sc, WPI_TX_CONFIG(qid), 0x80200008); } wpi_mem_unlock(sc); /* clear "radio off" and "disable command" bits (reversed logic) */ WPI_WRITE(sc, WPI_UCODE_CLR, WPI_RADIO_OFF); WPI_WRITE(sc, WPI_UCODE_CLR, WPI_DISABLE_CMD); /* clear any pending interrupts */ WPI_WRITE(sc, WPI_INTR, 0xffffffff); /* enable interrupts */ WPI_WRITE(sc, WPI_MASK, WPI_INTR_MASK); /* load firmware boot code into NIC */ err = wpi_load_microcode(sc); if (err != WPI_SUCCESS) { cmn_err(CE_WARN, "wpi_init(): failed to load microcode\n"); goto fail1; } /* load firmware .text segment into NIC */ err = wpi_load_firmware(sc, WPI_FW_TEXT); if (err != WPI_SUCCESS) { cmn_err(CE_WARN, "wpi_init(): " "failed to load firmware(text)\n"); goto fail1; } /* load firmware .data segment into NIC */ err = wpi_load_firmware(sc, WPI_FW_DATA); if (err != WPI_SUCCESS) { cmn_err(CE_WARN, "wpi_init(): " "failed to load firmware(data)\n"); goto fail1; } /* now press "execute" ;-) */ tmp = WPI_READ(sc, WPI_RESET); tmp &= ~(WPI_MASTER_DISABLED | WPI_STOP_MASTER | WPI_NEVO_RESET); WPI_WRITE(sc, WPI_RESET, tmp); /* ..and wait at most one second for adapter to initialize */ clk = ddi_get_lbolt() + drv_usectohz(2000000); while (!(sc->sc_flags & WPI_F_FW_INIT)) { if (cv_timedwait(&sc->sc_fw_cv, &sc->sc_glock, clk) < 0) break; } if (!(sc->sc_flags & WPI_F_FW_INIT)) { cmn_err(CE_WARN, "wpi_init(): timeout waiting for firmware init\n"); goto fail1; } /* wait for thermal sensors to calibrate */ for (ntries = 0; ntries < 1000; ntries++) { if (WPI_READ(sc, WPI_TEMPERATURE) != 0) break; DELAY(10); } if (ntries == 1000) { WPI_DBG((WPI_DEBUG_HW, "wpi_init(): timeout waiting for thermal sensors " "calibration\n")); } WPI_DBG((WPI_DEBUG_HW, "temperature %d\n", (int)WPI_READ(sc, WPI_TEMPERATURE))); err = wpi_config(sc); if (err) { cmn_err(CE_WARN, "wpi_init(): failed to configure device\n"); goto fail1; } mutex_exit(&sc->sc_glock); return (WPI_SUCCESS); fail1: err = WPI_FAIL; mutex_exit(&sc->sc_glock); return (err); } static void wpi_stop(wpi_sc_t *sc) { uint32_t tmp; int ac; mutex_enter(&sc->sc_glock); /* disable interrupts */ WPI_WRITE(sc, WPI_MASK, 0); WPI_WRITE(sc, WPI_INTR, WPI_INTR_MASK); WPI_WRITE(sc, WPI_INTR_STATUS, 0xff); WPI_WRITE(sc, WPI_INTR_STATUS, 0x00070000); wpi_mem_lock(sc); wpi_mem_write(sc, WPI_MEM_MODE, 0); wpi_mem_unlock(sc); /* reset all Tx rings */ for (ac = 0; ac < 4; ac++) wpi_reset_tx_ring(sc, &sc->sc_txq[ac]); wpi_reset_tx_ring(sc, &sc->sc_cmdq); wpi_reset_tx_ring(sc, &sc->sc_svcq); /* reset Rx ring */ wpi_reset_rx_ring(sc); wpi_mem_lock(sc); wpi_mem_write(sc, WPI_MEM_CLOCK2, 0x200); wpi_mem_unlock(sc); DELAY(5); wpi_stop_master(sc); sc->sc_tx_timer = 0; tmp = WPI_READ(sc, WPI_RESET); WPI_WRITE(sc, WPI_RESET, tmp | WPI_SW_RESET); mutex_exit(&sc->sc_glock); } /* * Naive implementation of the Adaptive Multi Rate Retry algorithm: * "IEEE 802.11 Rate Adaptation: A Practical Approach" * Mathieu Lacage, Hossein Manshaei, Thierry Turletti * INRIA Sophia - Projet Planete * http://www-sop.inria.fr/rapports/sophia/RR-5208.html */ #define is_success(amrr) \ ((amrr)->retrycnt < (amrr)->txcnt / 10) #define is_failure(amrr) \ ((amrr)->retrycnt > (amrr)->txcnt / 3) #define is_enough(amrr) \ ((amrr)->txcnt > 100) #define is_min_rate(in) \ ((in)->in_txrate == 0) #define is_max_rate(in) \ ((in)->in_txrate == (in)->in_rates.ir_nrates - 1) #define increase_rate(in) \ ((in)->in_txrate++) #define decrease_rate(in) \ ((in)->in_txrate--) #define reset_cnt(amrr) \ { (amrr)->txcnt = (amrr)->retrycnt = 0; } #define WPI_AMRR_MIN_SUCCESS_THRESHOLD 1 #define WPI_AMRR_MAX_SUCCESS_THRESHOLD 15 static void wpi_amrr_init(wpi_amrr_t *amrr) { amrr->success = 0; amrr->recovery = 0; amrr->txcnt = amrr->retrycnt = 0; amrr->success_threshold = WPI_AMRR_MIN_SUCCESS_THRESHOLD; } static void wpi_amrr_timeout(wpi_sc_t *sc) { ieee80211com_t *ic = &sc->sc_ic; WPI_DBG((WPI_DEBUG_RATECTL, "wpi_amrr_timeout() enter\n")); if (ic->ic_opmode == IEEE80211_M_STA) wpi_amrr_ratectl(NULL, ic->ic_bss); else ieee80211_iterate_nodes(&ic->ic_sta, wpi_amrr_ratectl, NULL); sc->sc_clk = ddi_get_lbolt(); } /* ARGSUSED */ static void wpi_amrr_ratectl(void *arg, ieee80211_node_t *in) { wpi_amrr_t *amrr = (wpi_amrr_t *)in; int need_change = 0; if (is_success(amrr) && is_enough(amrr)) { amrr->success++; if (amrr->success >= amrr->success_threshold && !is_max_rate(in)) { amrr->recovery = 1; amrr->success = 0; increase_rate(in); WPI_DBG((WPI_DEBUG_RATECTL, "AMRR increasing rate %d (txcnt=%d retrycnt=%d)\n", in->in_txrate, amrr->txcnt, amrr->retrycnt)); need_change = 1; } else { amrr->recovery = 0; } } else if (is_failure(amrr)) { amrr->success = 0; if (!is_min_rate(in)) { if (amrr->recovery) { amrr->success_threshold++; if (amrr->success_threshold > WPI_AMRR_MAX_SUCCESS_THRESHOLD) amrr->success_threshold = WPI_AMRR_MAX_SUCCESS_THRESHOLD; } else { amrr->success_threshold = WPI_AMRR_MIN_SUCCESS_THRESHOLD; } decrease_rate(in); WPI_DBG((WPI_DEBUG_RATECTL, "AMRR decreasing rate %d (txcnt=%d retrycnt=%d)\n", in->in_txrate, amrr->txcnt, amrr->retrycnt)); need_change = 1; } amrr->recovery = 0; /* paper is incorrect */ } if (is_enough(amrr) || need_change) reset_cnt(amrr); }