/* $OpenBSD: if_wpi.c,v 1.91 2009/08/10 17:21:15 damien Exp $ */ /*- * Copyright (c) 2006-2008 * 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. */ /* * Driver for Intel PRO/Wireless 3945ABG 802.11 network adapters. */ #include "bpfilter.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #if NBPFILTER > 0 #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include static const struct pci_matchid wpi_devices[] = { { PCI_VENDOR_INTEL, PCI_PRODUCT_INTEL_PRO_WL_3945ABG_1 }, { PCI_VENDOR_INTEL, PCI_PRODUCT_INTEL_PRO_WL_3945ABG_2 } }; int wpi_match(struct device *, void *, void *); void wpi_attach(struct device *, struct device *, void *); #ifndef SMALL_KERNEL void wpi_sensor_attach(struct wpi_softc *); #endif #if NBPFILTER > 0 void wpi_radiotap_attach(struct wpi_softc *); #endif void wpi_power(int, void *); int wpi_nic_lock(struct wpi_softc *); int wpi_read_prom_data(struct wpi_softc *, uint32_t, void *, int); int wpi_dma_contig_alloc(bus_dma_tag_t, struct wpi_dma_info *, void **, bus_size_t, bus_size_t); void wpi_dma_contig_free(struct wpi_dma_info *); int wpi_alloc_shared(struct wpi_softc *); void wpi_free_shared(struct wpi_softc *); int wpi_alloc_fwmem(struct wpi_softc *); void wpi_free_fwmem(struct wpi_softc *); int wpi_alloc_rx_ring(struct wpi_softc *, struct wpi_rx_ring *); void wpi_reset_rx_ring(struct wpi_softc *, struct wpi_rx_ring *); void wpi_free_rx_ring(struct wpi_softc *, struct wpi_rx_ring *); int wpi_alloc_tx_ring(struct wpi_softc *, struct wpi_tx_ring *, int); void wpi_reset_tx_ring(struct wpi_softc *, struct wpi_tx_ring *); void wpi_free_tx_ring(struct wpi_softc *, struct wpi_tx_ring *); int wpi_read_eeprom(struct wpi_softc *); void wpi_read_eeprom_channels(struct wpi_softc *, int); void wpi_read_eeprom_group(struct wpi_softc *, int); struct ieee80211_node *wpi_node_alloc(struct ieee80211com *); void wpi_newassoc(struct ieee80211com *, struct ieee80211_node *, int); int wpi_media_change(struct ifnet *); int wpi_newstate(struct ieee80211com *, enum ieee80211_state, int); void wpi_iter_func(void *, struct ieee80211_node *); void wpi_calib_timeout(void *); int wpi_ccmp_decap(struct wpi_softc *, struct mbuf *, struct ieee80211_key *); void wpi_rx_done(struct wpi_softc *, struct wpi_rx_desc *, struct wpi_rx_data *); void wpi_tx_done(struct wpi_softc *, struct wpi_rx_desc *); void wpi_cmd_done(struct wpi_softc *, struct wpi_rx_desc *); void wpi_notif_intr(struct wpi_softc *); void wpi_fatal_intr(struct wpi_softc *); int wpi_intr(void *); int wpi_tx(struct wpi_softc *, struct mbuf *, struct ieee80211_node *); void wpi_start(struct ifnet *); void wpi_watchdog(struct ifnet *); int wpi_ioctl(struct ifnet *, u_long, caddr_t); int wpi_cmd(struct wpi_softc *, int, const void *, int, int); int wpi_mrr_setup(struct wpi_softc *); void wpi_updateedca(struct ieee80211com *); void wpi_set_led(struct wpi_softc *, uint8_t, uint8_t, uint8_t); int wpi_set_timing(struct wpi_softc *, struct ieee80211_node *); void wpi_power_calibration(struct wpi_softc *, int); int wpi_set_txpower(struct wpi_softc *, int); int wpi_get_power_index(struct wpi_softc *, struct wpi_power_group *, struct ieee80211_channel *, int); int wpi_set_pslevel(struct wpi_softc *, int, int, int); int wpi_config(struct wpi_softc *); int wpi_scan(struct wpi_softc *, uint16_t); int wpi_auth(struct wpi_softc *); int wpi_run(struct wpi_softc *); int wpi_set_key(struct ieee80211com *, struct ieee80211_node *, struct ieee80211_key *); void wpi_delete_key(struct ieee80211com *, struct ieee80211_node *, struct ieee80211_key *); int wpi_post_alive(struct wpi_softc *); int wpi_load_bootcode(struct wpi_softc *, const uint8_t *, int); int wpi_load_firmware(struct wpi_softc *); int wpi_read_firmware(struct wpi_softc *); int wpi_clock_wait(struct wpi_softc *); int wpi_apm_init(struct wpi_softc *); void wpi_apm_stop_master(struct wpi_softc *); void wpi_apm_stop(struct wpi_softc *); void wpi_nic_config(struct wpi_softc *); int wpi_hw_init(struct wpi_softc *); void wpi_hw_stop(struct wpi_softc *); int wpi_init(struct ifnet *); void wpi_stop(struct ifnet *, int); #ifdef WPI_DEBUG #define DPRINTF(x) do { if (wpi_debug > 0) printf x; } while (0) #define DPRINTFN(n, x) do { if (wpi_debug >= (n)) printf x; } while (0) int wpi_debug = 0; #else #define DPRINTF(x) #define DPRINTFN(n, x) #endif struct cfdriver wpi_cd = { NULL, "wpi", DV_IFNET }; struct cfattach wpi_ca = { sizeof (struct wpi_softc), wpi_match, wpi_attach }; int wpi_match(struct device *parent, void *match, void *aux) { return pci_matchbyid((struct pci_attach_args *)aux, wpi_devices, nitems(wpi_devices)); } void wpi_attach(struct device *parent, struct device *self, void *aux) { struct wpi_softc *sc = (struct wpi_softc *)self; struct ieee80211com *ic = &sc->sc_ic; struct ifnet *ifp = &ic->ic_if; struct pci_attach_args *pa = aux; const char *intrstr; pci_intr_handle_t ih; pcireg_t memtype, reg; int i, error; sc->sc_pct = pa->pa_pc; sc->sc_pcitag = pa->pa_tag; sc->sc_dmat = pa->pa_dmat; /* * Get the offset of the PCI Express Capability Structure in PCI * Configuration Space (the vendor driver hard-codes it as E0h.) */ error = pci_get_capability(sc->sc_pct, sc->sc_pcitag, PCI_CAP_PCIEXPRESS, &sc->sc_cap_off, NULL); if (error == 0) { printf(": PCIe capability structure not found!\n"); return; } /* Clear device-specific "PCI retry timeout" register (41h). */ reg = pci_conf_read(sc->sc_pct, sc->sc_pcitag, 0x40); reg &= ~0xff00; pci_conf_write(sc->sc_pct, sc->sc_pcitag, 0x40, reg); memtype = pci_mapreg_type(pa->pa_pc, pa->pa_tag, WPI_PCI_BAR0); error = pci_mapreg_map(pa, WPI_PCI_BAR0, memtype, 0, &sc->sc_st, &sc->sc_sh, NULL, &sc->sc_sz, 0); if (error != 0) { printf(": can't map mem space\n"); return; } /* Install interrupt handler. */ if (pci_intr_map(pa, &ih) != 0) { printf(": can't map interrupt\n"); return; } intrstr = pci_intr_string(sc->sc_pct, ih); sc->sc_ih = pci_intr_establish(sc->sc_pct, ih, IPL_NET, wpi_intr, sc, sc->sc_dev.dv_xname); if (sc->sc_ih == NULL) { printf(": can't establish interrupt"); if (intrstr != NULL) printf(" at %s", intrstr); printf("\n"); return; } printf(": %s", intrstr); /* Power ON adapter. */ if ((error = wpi_apm_init(sc)) != 0) { printf(": could not power ON adapter\n"); return; } /* Read MAC address, channels, etc from EEPROM. */ if ((error = wpi_read_eeprom(sc)) != 0) { printf(": could not read EEPROM\n"); return; } /* Allocate DMA memory for firmware transfers. */ if ((error = wpi_alloc_fwmem(sc)) != 0) { printf(": could not allocate memory for firmware\n"); return; } /* Allocate shared area. */ if ((error = wpi_alloc_shared(sc)) != 0) { printf(": could not allocate shared area\n"); goto fail1; } /* Allocate TX rings. */ for (i = 0; i < WPI_NTXQUEUES; i++) { if ((error = wpi_alloc_tx_ring(sc, &sc->txq[i], i)) != 0) { printf(": could not allocate TX ring %d\n", i); goto fail2; } } /* Allocate RX ring. */ if ((error = wpi_alloc_rx_ring(sc, &sc->rxq)) != 0) { printf(": could not allocate Rx ring\n"); goto fail2; } /* Power OFF adapter. */ wpi_apm_stop(sc); /* Clear pending interrupts. */ WPI_WRITE(sc, WPI_INT, 0xffffffff); ic->ic_phytype = IEEE80211_T_OFDM; /* not only, but not used */ ic->ic_opmode = IEEE80211_M_STA; /* default to BSS mode */ ic->ic_state = IEEE80211_S_INIT; /* Set device capabilities. */ ic->ic_caps = IEEE80211_C_WEP | /* WEP */ IEEE80211_C_RSN | /* WPA/RSN */ IEEE80211_C_MONITOR | /* monitor mode supported */ IEEE80211_C_SHSLOT | /* short slot time supported */ IEEE80211_C_SHPREAMBLE | /* short preamble supported */ IEEE80211_C_PMGT; /* power saving supported */ /* Set supported rates. */ ic->ic_sup_rates[IEEE80211_MODE_11B] = ieee80211_std_rateset_11b; ic->ic_sup_rates[IEEE80211_MODE_11G] = ieee80211_std_rateset_11g; if (sc->sc_flags & WPI_FLAG_HAS_5GHZ) { ic->ic_sup_rates[IEEE80211_MODE_11A] = ieee80211_std_rateset_11a; } /* IBSS channel undefined for now. */ ic->ic_ibss_chan = &ic->ic_channels[0]; ifp->if_softc = sc; ifp->if_flags = IFF_BROADCAST | IFF_SIMPLEX | IFF_MULTICAST; ifp->if_init = wpi_init; ifp->if_ioctl = wpi_ioctl; ifp->if_start = wpi_start; ifp->if_watchdog = wpi_watchdog; IFQ_SET_READY(&ifp->if_snd); memcpy(ifp->if_xname, sc->sc_dev.dv_xname, IFNAMSIZ); if_attach(ifp); ieee80211_ifattach(ifp); ic->ic_node_alloc = wpi_node_alloc; ic->ic_newassoc = wpi_newassoc; ic->ic_updateedca = wpi_updateedca; ic->ic_set_key = wpi_set_key; ic->ic_delete_key = wpi_delete_key; /* Override 802.11 state transition machine. */ sc->sc_newstate = ic->ic_newstate; ic->ic_newstate = wpi_newstate; ieee80211_media_init(ifp, wpi_media_change, ieee80211_media_status); sc->amrr.amrr_min_success_threshold = 1; sc->amrr.amrr_max_success_threshold = 15; #ifndef SMALL_KERNEL wpi_sensor_attach(sc); #endif #if NBPFILTER > 0 wpi_radiotap_attach(sc); #endif timeout_set(&sc->calib_to, wpi_calib_timeout, sc); sc->powerhook = powerhook_establish(wpi_power, sc); return; /* Free allocated memory if something failed during attachment. */ fail2: while (--i >= 0) wpi_free_tx_ring(sc, &sc->txq[i]); wpi_free_shared(sc); fail1: wpi_free_fwmem(sc); } #ifndef SMALL_KERNEL /* * Attach the adapter's on-board thermal sensor to the sensors framework. */ void wpi_sensor_attach(struct wpi_softc *sc) { strlcpy(sc->sensordev.xname, sc->sc_dev.dv_xname, sizeof sc->sensordev.xname); strlcpy(sc->sensor.desc, "temperature 0 - 285", sizeof sc->sensor.desc); sc->sensor.type = SENSOR_INTEGER; /* not in muK! */ /* Temperature is not valid unless interface is up. */ sc->sensor.flags = SENSOR_FINVALID; sensor_attach(&sc->sensordev, &sc->sensor); sensordev_install(&sc->sensordev); } #endif #if NBPFILTER > 0 /* * Attach the interface to 802.11 radiotap. */ void wpi_radiotap_attach(struct wpi_softc *sc) { bpfattach(&sc->sc_drvbpf, &sc->sc_ic.ic_if, DLT_IEEE802_11_RADIO, sizeof (struct ieee80211_frame) + IEEE80211_RADIOTAP_HDRLEN); 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(WPI_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(WPI_TX_RADIOTAP_PRESENT); } #endif void wpi_power(int why, void *arg) { struct wpi_softc *sc = arg; struct ifnet *ifp; pcireg_t reg; int s; if (why != PWR_RESUME) return; /* Clear device-specific "PCI retry timeout" register (41h). */ reg = pci_conf_read(sc->sc_pct, sc->sc_pcitag, 0x40); reg &= ~0xff00; pci_conf_write(sc->sc_pct, sc->sc_pcitag, 0x40, reg); s = splnet(); ifp = &sc->sc_ic.ic_if; if (ifp->if_flags & IFF_UP) { ifp->if_init(ifp); if (ifp->if_flags & IFF_RUNNING) ifp->if_start(ifp); } splx(s); } int wpi_nic_lock(struct wpi_softc *sc) { int ntries; /* Request exclusive access to NIC. */ WPI_SETBITS(sc, WPI_GP_CNTRL, WPI_GP_CNTRL_MAC_ACCESS_REQ); /* Spin until we actually get the lock. */ for (ntries = 0; ntries < 1000; ntries++) { if ((WPI_READ(sc, WPI_GP_CNTRL) & (WPI_GP_CNTRL_MAC_ACCESS_ENA | WPI_GP_CNTRL_SLEEP)) == WPI_GP_CNTRL_MAC_ACCESS_ENA) return 0; DELAY(10); } return ETIMEDOUT; } static __inline void wpi_nic_unlock(struct wpi_softc *sc) { WPI_CLRBITS(sc, WPI_GP_CNTRL, WPI_GP_CNTRL_MAC_ACCESS_REQ); } static __inline uint32_t wpi_prph_read(struct wpi_softc *sc, uint32_t addr) { WPI_WRITE(sc, WPI_PRPH_RADDR, WPI_PRPH_DWORD | addr); return WPI_READ(sc, WPI_PRPH_RDATA); } static __inline void wpi_prph_write(struct wpi_softc *sc, uint32_t addr, uint32_t data) { WPI_WRITE(sc, WPI_PRPH_WADDR, WPI_PRPH_DWORD | addr); WPI_WRITE(sc, WPI_PRPH_WDATA, data); } static __inline void wpi_prph_setbits(struct wpi_softc *sc, uint32_t addr, uint32_t mask) { wpi_prph_write(sc, addr, wpi_prph_read(sc, addr) | mask); } static __inline void wpi_prph_clrbits(struct wpi_softc *sc, uint32_t addr, uint32_t mask) { wpi_prph_write(sc, addr, wpi_prph_read(sc, addr) & ~mask); } static __inline void wpi_prph_write_region_4(struct wpi_softc *sc, uint32_t addr, const uint32_t *data, int count) { for (; count > 0; count--, data++, addr += 4) wpi_prph_write(sc, addr, *data); } static __inline uint32_t wpi_mem_read(struct wpi_softc *sc, uint32_t addr) { WPI_WRITE(sc, WPI_MEM_RADDR, addr); return WPI_READ(sc, WPI_MEM_RDATA); } static __inline void wpi_mem_write(struct wpi_softc *sc, uint32_t addr, uint32_t data) { WPI_WRITE(sc, WPI_MEM_WADDR, addr); WPI_WRITE(sc, WPI_MEM_WDATA, data); } static __inline void wpi_mem_read_region_4(struct wpi_softc *sc, uint32_t addr, uint32_t *data, int count) { for (; count > 0; count--, addr += 4) *data++ = wpi_mem_read(sc, addr); } int wpi_read_prom_data(struct wpi_softc *sc, uint32_t addr, void *data, int count) { uint8_t *out = data; uint32_t val; int error, ntries; if ((error = wpi_nic_lock(sc)) != 0) return error; for (; count > 0; count -= 2, addr++) { WPI_WRITE(sc, WPI_EEPROM, addr << 2); WPI_CLRBITS(sc, WPI_EEPROM, WPI_EEPROM_CMD); for (ntries = 0; ntries < 10; ntries++) { val = WPI_READ(sc, WPI_EEPROM); if (val & WPI_EEPROM_READ_VALID) break; DELAY(5); } if (ntries == 10) { printf("%s: could not read EEPROM\n", sc->sc_dev.dv_xname); return ETIMEDOUT; } *out++ = val >> 16; if (count > 1) *out++ = val >> 24; } wpi_nic_unlock(sc); return 0; } int wpi_dma_contig_alloc(bus_dma_tag_t tag, struct wpi_dma_info *dma, void **kvap, bus_size_t size, bus_size_t alignment) { int nsegs, error; dma->tag = tag; dma->size = size; error = bus_dmamap_create(tag, size, 1, size, 0, BUS_DMA_NOWAIT, &dma->map); if (error != 0) goto fail; error = bus_dmamem_alloc(tag, size, alignment, 0, &dma->seg, 1, &nsegs, BUS_DMA_NOWAIT | BUS_DMA_ZERO); if (error != 0) goto fail; error = bus_dmamem_map(tag, &dma->seg, 1, size, &dma->vaddr, BUS_DMA_NOWAIT); if (error != 0) goto fail; error = bus_dmamap_load_raw(tag, dma->map, &dma->seg, 1, size, BUS_DMA_NOWAIT); if (error != 0) goto fail; bus_dmamap_sync(tag, dma->map, 0, size, BUS_DMASYNC_PREWRITE); dma->paddr = dma->map->dm_segs[0].ds_addr; if (kvap != NULL) *kvap = dma->vaddr; return 0; fail: wpi_dma_contig_free(dma); return error; } void wpi_dma_contig_free(struct wpi_dma_info *dma) { if (dma->map != NULL) { if (dma->vaddr != NULL) { bus_dmamap_sync(dma->tag, dma->map, 0, dma->size, BUS_DMASYNC_POSTREAD | BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(dma->tag, dma->map); bus_dmamem_unmap(dma->tag, dma->vaddr, dma->size); bus_dmamem_free(dma->tag, &dma->seg, 1); dma->vaddr = NULL; } bus_dmamap_destroy(dma->tag, dma->map); dma->map = NULL; } } int wpi_alloc_shared(struct wpi_softc *sc) { /* Shared buffer must be aligned on a 4KB boundary. */ return wpi_dma_contig_alloc(sc->sc_dmat, &sc->shared_dma, (void **)&sc->shared, sizeof (struct wpi_shared), 4096); } void wpi_free_shared(struct wpi_softc *sc) { wpi_dma_contig_free(&sc->shared_dma); } int wpi_alloc_fwmem(struct wpi_softc *sc) { /* Allocate enough contiguous space to store text and data. */ return wpi_dma_contig_alloc(sc->sc_dmat, &sc->fw_dma, NULL, WPI_FW_TEXT_MAXSZ + WPI_FW_DATA_MAXSZ, 16); } void wpi_free_fwmem(struct wpi_softc *sc) { wpi_dma_contig_free(&sc->fw_dma); } int wpi_alloc_rx_ring(struct wpi_softc *sc, struct wpi_rx_ring *ring) { bus_size_t size; int i, error; ring->cur = 0; /* Allocate RX descriptors (16KB aligned.) */ size = WPI_RX_RING_COUNT * sizeof (uint32_t); error = wpi_dma_contig_alloc(sc->sc_dmat, &ring->desc_dma, (void **)&ring->desc, size, 16 * 1024); if (error != 0) { printf("%s: could not allocate RX ring DMA memory\n", sc->sc_dev.dv_xname); goto fail; } /* * Allocate and map RX buffers. */ for (i = 0; i < WPI_RX_RING_COUNT; i++) { struct wpi_rx_data *data = &ring->data[i]; error = bus_dmamap_create(sc->sc_dmat, WPI_RBUF_SIZE, 1, WPI_RBUF_SIZE, 0, BUS_DMA_NOWAIT, &data->map); if (error != 0) { printf("%s: could not create RX buf DMA map\n", sc->sc_dev.dv_xname); goto fail; } data->m = MCLGETI(NULL, M_DONTWAIT, NULL, WPI_RBUF_SIZE); if (data->m == NULL) { printf("%s: could not allocate RX mbuf\n", sc->sc_dev.dv_xname); error = ENOBUFS; goto fail; } error = bus_dmamap_load(sc->sc_dmat, data->map, mtod(data->m, void *), WPI_RBUF_SIZE, NULL, BUS_DMA_NOWAIT); if (error != 0) { printf("%s: can't map mbuf (error %d)\n", sc->sc_dev.dv_xname, error); goto fail; } /* Set physical address of RX buffer. */ ring->desc[i] = htole32(data->map->dm_segs[0].ds_addr); } bus_dmamap_sync(sc->sc_dmat, ring->desc_dma.map, 0, size, BUS_DMASYNC_PREWRITE); return 0; fail: wpi_free_rx_ring(sc, ring); return error; } void wpi_reset_rx_ring(struct wpi_softc *sc, struct wpi_rx_ring *ring) { int ntries; if (wpi_nic_lock(sc) == 0) { WPI_WRITE(sc, WPI_FH_RX_CONFIG, 0); for (ntries = 0; ntries < 100; ntries++) { if (WPI_READ(sc, WPI_FH_RX_STATUS) & WPI_FH_RX_STATUS_IDLE) break; DELAY(10); } wpi_nic_unlock(sc); } ring->cur = 0; } void wpi_free_rx_ring(struct wpi_softc *sc, struct wpi_rx_ring *ring) { int i; wpi_dma_contig_free(&ring->desc_dma); for (i = 0; i < WPI_RX_RING_COUNT; i++) { struct wpi_rx_data *data = &ring->data[i]; if (data->m != NULL) { bus_dmamap_sync(sc->sc_dmat, data->map, 0, data->map->dm_mapsize, BUS_DMASYNC_POSTREAD); bus_dmamap_unload(sc->sc_dmat, data->map); m_freem(data->m); } if (data->map != NULL) bus_dmamap_destroy(sc->sc_dmat, data->map); } } int wpi_alloc_tx_ring(struct wpi_softc *sc, struct wpi_tx_ring *ring, int qid) { bus_addr_t paddr; bus_size_t size; int i, error; ring->qid = qid; ring->queued = 0; ring->cur = 0; /* Allocate TX descriptors (16KB aligned.) */ size = WPI_TX_RING_COUNT * sizeof (struct wpi_tx_desc); error = wpi_dma_contig_alloc(sc->sc_dmat, &ring->desc_dma, (void **)&ring->desc, size, 16 * 1024); if (error != 0) { printf("%s: could not allocate TX ring DMA memory\n", sc->sc_dev.dv_xname); goto fail; } /* Update shared area with ring's physical address. */ sc->shared->txbase[qid] = htole32(ring->desc_dma.paddr); bus_dmamap_sync(sc->sc_dmat, sc->shared_dma.map, 0, sizeof (struct wpi_shared), BUS_DMASYNC_PREWRITE); /* * We only use rings 0 through 4 (4 EDCA + cmd) so there is no need * to allocate commands space for other rings. * XXX Do we really need to allocate descriptors for other rings? */ if (qid > 4) return 0; size = WPI_TX_RING_COUNT * sizeof (struct wpi_tx_cmd); error = wpi_dma_contig_alloc(sc->sc_dmat, &ring->cmd_dma, (void **)&ring->cmd, size, 4); if (error != 0) { printf("%s: could not allocate TX cmd DMA memory\n", sc->sc_dev.dv_xname); goto fail; } paddr = ring->cmd_dma.paddr; for (i = 0; i < WPI_TX_RING_COUNT; i++) { struct wpi_tx_data *data = &ring->data[i]; data->cmd_paddr = paddr; paddr += sizeof (struct wpi_tx_cmd); error = bus_dmamap_create(sc->sc_dmat, MCLBYTES, WPI_MAX_SCATTER - 1, MCLBYTES, 0, BUS_DMA_NOWAIT, &data->map); if (error != 0) { printf("%s: could not create TX buf DMA map\n", sc->sc_dev.dv_xname); goto fail; } } return 0; fail: wpi_free_tx_ring(sc, ring); return error; } void wpi_reset_tx_ring(struct wpi_softc *sc, struct wpi_tx_ring *ring) { int i; for (i = 0; i < WPI_TX_RING_COUNT; i++) { struct wpi_tx_data *data = &ring->data[i]; if (data->m != NULL) { bus_dmamap_sync(sc->sc_dmat, data->map, 0, data->map->dm_mapsize, BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(sc->sc_dmat, data->map); m_freem(data->m); data->m = NULL; } } /* Clear TX descriptors. */ memset(ring->desc, 0, ring->desc_dma.size); sc->qfullmsk &= ~(1 << ring->qid); ring->queued = 0; ring->cur = 0; } void wpi_free_tx_ring(struct wpi_softc *sc, struct wpi_tx_ring *ring) { int i; wpi_dma_contig_free(&ring->desc_dma); wpi_dma_contig_free(&ring->cmd_dma); for (i = 0; i < WPI_TX_RING_COUNT; i++) { struct wpi_tx_data *data = &ring->data[i]; if (data->m != NULL) { bus_dmamap_sync(sc->sc_dmat, data->map, 0, data->map->dm_mapsize, BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(sc->sc_dmat, data->map); m_freem(data->m); } if (data->map != NULL) bus_dmamap_destroy(sc->sc_dmat, data->map); } } int wpi_read_eeprom(struct wpi_softc *sc) { struct ieee80211com *ic = &sc->sc_ic; char domain[4]; int i; if ((WPI_READ(sc, WPI_EEPROM_GP) & 0x6) == 0) { printf("%s: bad EEPROM signature\n", sc->sc_dev.dv_xname); return EIO; } /* Clear HW ownership of EEPROM. */ WPI_CLRBITS(sc, WPI_EEPROM_GP, WPI_EEPROM_GP_IF_OWNER); wpi_read_prom_data(sc, WPI_EEPROM_CAPABILITIES, &sc->cap, 1); wpi_read_prom_data(sc, WPI_EEPROM_REVISION, &sc->rev, 2); wpi_read_prom_data(sc, WPI_EEPROM_TYPE, &sc->type, 1); DPRINTF(("cap=%x rev=%x type=%x\n", sc->cap, letoh16(sc->rev), sc->type)); /* Read and print regulatory domain (4 ASCII characters.) */ wpi_read_prom_data(sc, WPI_EEPROM_DOMAIN, domain, 4); printf(", %.4s", domain); /* Read and print MAC address. */ wpi_read_prom_data(sc, WPI_EEPROM_MAC, ic->ic_myaddr, 6); printf(", address %s\n", ether_sprintf(ic->ic_myaddr)); /* Read the list of authorized channels. */ for (i = 0; i < WPI_CHAN_BANDS_COUNT; i++) wpi_read_eeprom_channels(sc, i); /* Read the list of TX power groups. */ for (i = 0; i < WPI_POWER_GROUPS_COUNT; i++) wpi_read_eeprom_group(sc, i); return 0; } void wpi_read_eeprom_channels(struct wpi_softc *sc, int n) { struct ieee80211com *ic = &sc->sc_ic; const struct wpi_chan_band *band = &wpi_bands[n]; struct wpi_eeprom_chan channels[WPI_MAX_CHAN_PER_BAND]; int chan, i; wpi_read_prom_data(sc, band->addr, channels, band->nchan * sizeof (struct wpi_eeprom_chan)); for (i = 0; i < band->nchan; i++) { if (!(channels[i].flags & WPI_EEPROM_CHAN_VALID)) continue; chan = band->chan[i]; if (n == 0) { /* 2GHz band */ ic->ic_channels[chan].ic_freq = ieee80211_ieee2mhz(chan, IEEE80211_CHAN_2GHZ); ic->ic_channels[chan].ic_flags = IEEE80211_CHAN_CCK | IEEE80211_CHAN_OFDM | IEEE80211_CHAN_DYN | IEEE80211_CHAN_2GHZ; } else { /* 5GHz band */ /* * Some adapters support channels 7, 8, 11 and 12 * both in the 2GHz and 4.9GHz bands. * Because of limitations in our net80211 layer, * we don't support them in the 4.9GHz band. */ if (chan <= 14) continue; ic->ic_channels[chan].ic_freq = ieee80211_ieee2mhz(chan, IEEE80211_CHAN_5GHZ); ic->ic_channels[chan].ic_flags = IEEE80211_CHAN_A; } /* Is active scan allowed on this channel? */ if (!(channels[i].flags & WPI_EEPROM_CHAN_ACTIVE)) { ic->ic_channels[chan].ic_flags |= IEEE80211_CHAN_PASSIVE; } /* Save maximum allowed TX power for this channel. */ sc->maxpwr[chan] = channels[i].maxpwr; DPRINTF(("adding chan %d flags=0x%x maxpwr=%d\n", chan, channels[i].flags, sc->maxpwr[chan])); } } void wpi_read_eeprom_group(struct wpi_softc *sc, int n) { struct wpi_power_group *group = &sc->groups[n]; struct wpi_eeprom_group rgroup; int i; wpi_read_prom_data(sc, WPI_EEPROM_POWER_GRP + n * 32, &rgroup, sizeof rgroup); /* Save TX power group information. */ group->chan = rgroup.chan; group->maxpwr = rgroup.maxpwr; /* Retrieve temperature at which the samples were taken. */ group->temp = (int16_t)letoh16(rgroup.temp); DPRINTF(("power group %d: chan=%d maxpwr=%d temp=%d\n", n, group->chan, group->maxpwr, group->temp)); for (i = 0; i < WPI_SAMPLES_COUNT; i++) { group->samples[i].index = rgroup.samples[i].index; group->samples[i].power = rgroup.samples[i].power; DPRINTF(("\tsample %d: index=%d power=%d\n", i, group->samples[i].index, group->samples[i].power)); } } struct ieee80211_node * wpi_node_alloc(struct ieee80211com *ic) { return malloc(sizeof (struct wpi_node), M_DEVBUF, M_NOWAIT | M_ZERO); } void wpi_newassoc(struct ieee80211com *ic, struct ieee80211_node *ni, int isnew) { struct wpi_softc *sc = ic->ic_if.if_softc; struct wpi_node *wn = (void *)ni; uint8_t rate; int ridx, i; ieee80211_amrr_node_init(&sc->amrr, &wn->amn); for (i = 0; i < ni->ni_rates.rs_nrates; i++) { rate = ni->ni_rates.rs_rates[i] & IEEE80211_RATE_VAL; /* Map 802.11 rate to HW rate index. */ for (ridx = 0; ridx <= WPI_RIDX_MAX; ridx++) if (wpi_rates[ridx].rate == rate) break; wn->ridx[i] = ridx; /* Initial TX rate <= 24Mbps. */ if (rate <= 48) ni->ni_txrate = i; } } int wpi_media_change(struct ifnet *ifp) { struct wpi_softc *sc = ifp->if_softc; struct ieee80211com *ic = &sc->sc_ic; uint8_t rate, ridx; int error; error = ieee80211_media_change(ifp); if (error != ENETRESET) return error; if (ic->ic_fixed_rate != -1) { rate = ic->ic_sup_rates[ic->ic_curmode]. rs_rates[ic->ic_fixed_rate] & IEEE80211_RATE_VAL; /* Map 802.11 rate to HW rate index. */ for (ridx = 0; ridx <= WPI_RIDX_MAX; ridx++) if (wpi_rates[ridx].rate == rate) break; sc->fixed_ridx = ridx; } if ((ifp->if_flags & (IFF_UP | IFF_RUNNING)) == (IFF_UP | IFF_RUNNING)) { wpi_stop(ifp, 0); error = wpi_init(ifp); } return error; } int wpi_newstate(struct ieee80211com *ic, enum ieee80211_state nstate, int arg) { struct ifnet *ifp = &ic->ic_if; struct wpi_softc *sc = ifp->if_softc; int error; timeout_del(&sc->calib_to); switch (nstate) { case IEEE80211_S_SCAN: /* Make the link LED blink while we're scanning. */ wpi_set_led(sc, WPI_LED_LINK, 20, 2); if ((error = wpi_scan(sc, IEEE80211_CHAN_2GHZ)) != 0) { printf("%s: could not initiate scan\n", sc->sc_dev.dv_xname); return error; } ic->ic_state = nstate; return 0; case IEEE80211_S_ASSOC: if (ic->ic_state != IEEE80211_S_RUN) break; /* FALLTHROUGH */ case IEEE80211_S_AUTH: /* Reset state to handle reassociations correctly. */ sc->rxon.associd = 0; sc->rxon.filter &= ~htole32(WPI_FILTER_BSS); if ((error = wpi_auth(sc)) != 0) { printf("%s: could not move to auth state\n", sc->sc_dev.dv_xname); return error; } break; case IEEE80211_S_RUN: if ((error = wpi_run(sc)) != 0) { printf("%s: could not move to run state\n", sc->sc_dev.dv_xname); return error; } break; case IEEE80211_S_INIT: break; } return sc->sc_newstate(ic, nstate, arg); } void wpi_iter_func(void *arg, struct ieee80211_node *ni) { struct wpi_softc *sc = arg; struct wpi_node *wn = (struct wpi_node *)ni; ieee80211_amrr_choose(&sc->amrr, ni, &wn->amn); } void wpi_calib_timeout(void *arg) { struct wpi_softc *sc = arg; struct ieee80211com *ic = &sc->sc_ic; int temp, s; /* Automatic rate control triggered every 500ms. */ if (ic->ic_fixed_rate == -1) { s = splnet(); if (ic->ic_opmode == IEEE80211_M_STA) wpi_iter_func(sc, ic->ic_bss); else ieee80211_iterate_nodes(ic, wpi_iter_func, sc); splx(s); } /* Update sensor. */ temp = (int)WPI_READ(sc, WPI_UCODE_GP2); sc->sensor.value = temp + 260; /* Force automatic TX power calibration every 60 secs. */ if (++sc->calib_cnt >= 120) { wpi_power_calibration(sc, temp); sc->calib_cnt = 0; } /* Automatic rate control triggered every 500ms. */ timeout_add_msec(&sc->calib_to, 500); } int wpi_ccmp_decap(struct wpi_softc *sc, struct mbuf *m, struct ieee80211_key *k) { struct ieee80211_frame *wh; uint64_t pn, *prsc; uint8_t *ivp; uint8_t tid; int hdrlen; wh = mtod(m, struct ieee80211_frame *); hdrlen = ieee80211_get_hdrlen(wh); ivp = (uint8_t *)wh + hdrlen; /* Check that ExtIV bit is be set. */ if (!(ivp[3] & IEEE80211_WEP_EXTIV)) { DPRINTF(("CCMP decap ExtIV not set\n")); return 1; } tid = ieee80211_has_qos(wh) ? ieee80211_get_qos(wh) & IEEE80211_QOS_TID : 0; prsc = &k->k_rsc[tid]; /* Extract the 48-bit PN from the CCMP header. */ pn = (uint64_t)ivp[0] | (uint64_t)ivp[1] << 8 | (uint64_t)ivp[4] << 16 | (uint64_t)ivp[5] << 24 | (uint64_t)ivp[6] << 32 | (uint64_t)ivp[7] << 40; if (pn <= *prsc) { /* * Not necessarily a replayed frame since we did not check * the sequence number of the 802.11 header yet. */ DPRINTF(("CCMP replayed\n")); return 1; } /* Update last seen packet number. */ *prsc = pn; /* Clear Protected bit and strip IV. */ wh->i_fc[1] &= ~IEEE80211_FC1_PROTECTED; ovbcopy(wh, mtod(m, caddr_t) + IEEE80211_CCMP_HDRLEN, hdrlen); m_adj(m, IEEE80211_CCMP_HDRLEN); /* Strip MIC. */ m_adj(m, -IEEE80211_CCMP_MICLEN); return 0; } void wpi_rx_done(struct wpi_softc *sc, struct wpi_rx_desc *desc, struct wpi_rx_data *data) { struct ieee80211com *ic = &sc->sc_ic; struct ifnet *ifp = &ic->ic_if; struct wpi_rx_ring *ring = &sc->rxq; struct wpi_rx_stat *stat; struct wpi_rx_head *head; struct wpi_rx_tail *tail; struct ieee80211_frame *wh; struct ieee80211_rxinfo rxi; struct ieee80211_node *ni; struct mbuf *m, *m1; uint32_t flags; int error; bus_dmamap_sync(sc->sc_dmat, data->map, 0, WPI_RBUF_SIZE, BUS_DMASYNC_POSTREAD); stat = (struct wpi_rx_stat *)(desc + 1); if (stat->len > WPI_STAT_MAXLEN) { printf("%s: invalid RX statistic header\n", sc->sc_dev.dv_xname); ifp->if_ierrors++; return; } head = (struct wpi_rx_head *)((caddr_t)(stat + 1) + stat->len); tail = (struct wpi_rx_tail *)((caddr_t)(head + 1) + letoh16(head->len)); flags = letoh32(tail->flags); /* Discard frames with a bad FCS early. */ if ((flags & WPI_RX_NOERROR) != WPI_RX_NOERROR) { DPRINTFN(2, ("rx tail flags error %x\n", flags)); ifp->if_ierrors++; return; } /* Discard frames that are too short. */ if (letoh16(head->len) < sizeof (*wh)) { DPRINTF(("frame too short: %d\n", letoh16(head->len))); ic->ic_stats.is_rx_tooshort++; ifp->if_ierrors++; return; } m1 = MCLGETI(NULL, M_DONTWAIT, NULL, WPI_RBUF_SIZE); if (m1 == NULL) { ic->ic_stats.is_rx_nombuf++; ifp->if_ierrors++; return; } bus_dmamap_unload(sc->sc_dmat, data->map); error = bus_dmamap_load(sc->sc_dmat, data->map, mtod(m1, void *), WPI_RBUF_SIZE, NULL, BUS_DMA_NOWAIT); if (error != 0) { m_freem(m1); /* Try to reload the old mbuf. */ error = bus_dmamap_load(sc->sc_dmat, data->map, mtod(data->m, void *), WPI_RBUF_SIZE, NULL, BUS_DMA_NOWAIT); if (error != 0) { panic("%s: could not load old RX mbuf", sc->sc_dev.dv_xname); } /* Physical address may have changed. */ ring->desc[ring->cur] = htole32(data->map->dm_segs[0].ds_addr); bus_dmamap_sync(sc->sc_dmat, ring->desc_dma.map, ring->cur * sizeof (uint32_t), sizeof (uint32_t), BUS_DMASYNC_PREWRITE); ifp->if_ierrors++; return; } m = data->m; data->m = m1; /* Update RX descriptor. */ ring->desc[ring->cur] = htole32(data->map->dm_segs[0].ds_addr); bus_dmamap_sync(sc->sc_dmat, ring->desc_dma.map, ring->cur * sizeof (uint32_t), sizeof (uint32_t), BUS_DMASYNC_PREWRITE); /* Finalize mbuf. */ m->m_pkthdr.rcvif = ifp; m->m_data = (caddr_t)(head + 1); m->m_pkthdr.len = m->m_len = letoh16(head->len); /* Grab a reference to the source node. */ wh = mtod(m, struct ieee80211_frame *); ni = ieee80211_find_rxnode(ic, wh); rxi.rxi_flags = 0; if ((wh->i_fc[1] & IEEE80211_FC1_PROTECTED) && !IEEE80211_IS_MULTICAST(wh->i_addr1) && (ni->ni_flags & IEEE80211_NODE_RXPROT) && ni->ni_pairwise_key.k_cipher == IEEE80211_CIPHER_CCMP) { if ((flags & WPI_RX_CIPHER_MASK) != WPI_RX_CIPHER_CCMP) { ic->ic_stats.is_ccmp_dec_errs++; ifp->if_ierrors++; m_freem(m); return; } /* Check whether decryption was successful or not. */ if ((flags & WPI_RX_DECRYPT_MASK) != WPI_RX_DECRYPT_OK) { DPRINTF(("CCMP decryption failed 0x%x\n", flags)); ic->ic_stats.is_ccmp_dec_errs++; ifp->if_ierrors++; m_freem(m); return; } if (wpi_ccmp_decap(sc, m, &ni->ni_pairwise_key) != 0) { ifp->if_ierrors++; m_freem(m); return; } rxi.rxi_flags |= IEEE80211_RXI_HWDEC; } #if NBPFILTER > 0 if (sc->sc_drvbpf != NULL) { struct mbuf mb; struct wpi_rx_radiotap_header *tap = &sc->sc_rxtap; tap->wr_flags = 0; if (letoh16(head->flags) & 0x4) tap->wr_flags |= IEEE80211_RADIOTAP_F_SHORTPRE; tap->wr_chan_freq = htole16(ic->ic_channels[head->chan].ic_freq); tap->wr_chan_flags = htole16(ic->ic_channels[head->chan].ic_flags); tap->wr_dbm_antsignal = (int8_t)(stat->rssi - WPI_RSSI_OFFSET); tap->wr_dbm_antnoise = (int8_t)letoh16(stat->noise); tap->wr_tsft = tail->tstamp; tap->wr_antenna = (letoh16(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; } mb.m_data = (caddr_t)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_mtap(sc->sc_drvbpf, &mb, BPF_DIRECTION_IN); } #endif /* Send the frame to the 802.11 layer. */ rxi.rxi_rssi = stat->rssi; rxi.rxi_tstamp = 0; /* unused */ ieee80211_input(ifp, m, ni, &rxi); /* Node is no longer needed. */ ieee80211_release_node(ic, ni); } void wpi_tx_done(struct wpi_softc *sc, struct wpi_rx_desc *desc) { struct ieee80211com *ic = &sc->sc_ic; struct ifnet *ifp = &ic->ic_if; struct wpi_tx_ring *ring = &sc->txq[desc->qid & 0x3]; struct wpi_tx_data *data = &ring->data[desc->idx]; struct wpi_tx_stat *stat = (struct wpi_tx_stat *)(desc + 1); struct wpi_node *wn = (struct wpi_node *)data->ni; /* Update rate control statistics. */ wn->amn.amn_txcnt++; if (stat->retrycnt > 0) wn->amn.amn_retrycnt++; if ((letoh32(stat->status) & 0xff) != 1) ifp->if_oerrors++; else ifp->if_opackets++; /* Unmap and free mbuf. */ bus_dmamap_sync(sc->sc_dmat, data->map, 0, data->map->dm_mapsize, BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(sc->sc_dmat, data->map); m_freem(data->m); data->m = NULL; ieee80211_release_node(ic, data->ni); data->ni = NULL; sc->sc_tx_timer = 0; if (--ring->queued < WPI_TX_RING_LOMARK) { sc->qfullmsk &= ~(1 << ring->qid); if (sc->qfullmsk == 0 && (ifp->if_flags & IFF_OACTIVE)) { ifp->if_flags &= ~IFF_OACTIVE; (*ifp->if_start)(ifp); } } } void wpi_cmd_done(struct wpi_softc *sc, struct wpi_rx_desc *desc) { struct wpi_tx_ring *ring = &sc->txq[4]; struct wpi_tx_data *data; if ((desc->qid & 7) != 4) return; /* Not a command ack. */ data = &ring->data[desc->idx]; /* If the command was mapped in an mbuf, free it. */ if (data->m != NULL) { bus_dmamap_sync(sc->sc_dmat, data->map, 0, data->map->dm_mapsize, BUS_DMASYNC_POSTWRITE); bus_dmamap_unload(sc->sc_dmat, data->map); m_freem(data->m); data->m = NULL; } wakeup(&ring->cmd[desc->idx]); } void wpi_notif_intr(struct wpi_softc *sc) { struct ieee80211com *ic = &sc->sc_ic; struct ifnet *ifp = &ic->ic_if; uint32_t hw; bus_dmamap_sync(sc->sc_dmat, sc->shared_dma.map, 0, sizeof (struct wpi_shared), BUS_DMASYNC_POSTREAD); hw = letoh32(sc->shared->next); while (sc->rxq.cur != hw) { struct wpi_rx_data *data = &sc->rxq.data[sc->rxq.cur]; struct wpi_rx_desc *desc; bus_dmamap_sync(sc->sc_dmat, data->map, 0, sizeof (*desc), BUS_DMASYNC_POSTREAD); desc = mtod(data->m, struct wpi_rx_desc *); DPRINTFN(4, ("rx notification qid=%x idx=%d flags=%x type=%d " "len=%d\n", desc->qid, desc->idx, desc->flags, desc->type, letoh32(desc->len))); if (!(desc->qid & 0x80)) /* Reply to a command. */ wpi_cmd_done(sc, desc); switch (desc->type) { case WPI_RX_DONE: /* An 802.11 frame has been received. */ wpi_rx_done(sc, desc, data); break; case WPI_TX_DONE: /* An 802.11 frame has been transmitted. */ wpi_tx_done(sc, desc); break; case WPI_UC_READY: { struct wpi_ucode_info *uc = (struct wpi_ucode_info *)(desc + 1); /* The microcontroller is ready. */ bus_dmamap_sync(sc->sc_dmat, data->map, sizeof (*desc), sizeof (*uc), BUS_DMASYNC_POSTREAD); DPRINTF(("microcode alive notification version %x " "alive %x\n", letoh32(uc->version), letoh32(uc->valid))); if (letoh32(uc->valid) != 1) { printf("%s: microcontroller initialization " "failed\n", sc->sc_dev.dv_xname); } if (uc->subtype != WPI_UCODE_INIT) { /* Save the address of the error log. */ sc->errptr = letoh32(uc->errptr); } break; } case WPI_STATE_CHANGED: { uint32_t *status = (uint32_t *)(desc + 1); /* Enabled/disabled notification. */ bus_dmamap_sync(sc->sc_dmat, data->map, sizeof (*desc), sizeof (*status), BUS_DMASYNC_POSTREAD); DPRINTF(("state changed to %x\n", letoh32(*status))); if (letoh32(*status) & 1) { /* The radio button has to be pushed. */ printf("%s: Radio transmitter is off\n", sc->sc_dev.dv_xname); /* Turn the interface down. */ ifp->if_flags &= ~IFF_UP; wpi_stop(ifp, 1); return; /* No further processing. */ } break; } case WPI_START_SCAN: { struct wpi_start_scan *scan = (struct wpi_start_scan *)(desc + 1); bus_dmamap_sync(sc->sc_dmat, data->map, sizeof (*desc), sizeof (*scan), BUS_DMASYNC_POSTREAD); DPRINTFN(2, ("scanning channel %d status %x\n", scan->chan, letoh32(scan->status))); /* Fix current channel. */ ic->ic_bss->ni_chan = &ic->ic_channels[scan->chan]; break; } case WPI_STOP_SCAN: { struct wpi_stop_scan *scan = (struct wpi_stop_scan *)(desc + 1); bus_dmamap_sync(sc->sc_dmat, data->map, sizeof (*desc), sizeof (*scan), BUS_DMASYNC_POSTREAD); DPRINTF(("scan finished nchan=%d status=%d chan=%d\n", scan->nchan, scan->status, scan->chan)); if (scan->status == 1 && scan->chan <= 14 && (sc->sc_flags & WPI_FLAG_HAS_5GHZ)) { /* * We just finished scanning 2GHz channels, * start scanning 5GHz ones. */ if (wpi_scan(sc, IEEE80211_CHAN_5GHZ) == 0) break; } ieee80211_end_scan(ifp); break; } } sc->rxq.cur = (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_FH_RX_WPTR, hw & ~7); } /* * Dump the error log of the firmware when a firmware panic occurs. Although * we can't debug the firmware because it is neither open source nor free, it * can help us to identify certain classes of problems. */ void wpi_fatal_intr(struct wpi_softc *sc) { #define N(a) (sizeof (a) / sizeof ((a)[0])) struct wpi_fwdump dump; uint32_t i, offset, count; /* Check that the error log address is valid. */ if (sc->errptr < WPI_FW_DATA_BASE || sc->errptr + sizeof (dump) > WPI_FW_DATA_BASE + WPI_FW_DATA_MAXSZ) { printf("%s: bad firmware error log address 0x%08x\n", sc->sc_dev.dv_xname, sc->errptr); return; } if (wpi_nic_lock(sc) != 0) { printf("%s: could not read firmware error log\n", sc->sc_dev.dv_xname); return; } /* Read number of entries in the log. */ count = wpi_mem_read(sc, sc->errptr); if (count == 0 || count * sizeof (dump) > WPI_FW_DATA_MAXSZ) { printf("%s: invalid count field (count=%u)\n", sc->sc_dev.dv_xname, count); wpi_nic_unlock(sc); return; } /* Skip "count" field. */ offset = sc->errptr + sizeof (uint32_t); printf("firmware error log (count=%u):\n", count); for (i = 0; i < count; i++) { wpi_mem_read_region_4(sc, offset, (uint32_t *)&dump, sizeof (dump) / sizeof (uint32_t)); printf(" error type = \"%s\" (0x%08X)\n", (dump.desc < N(wpi_fw_errmsg)) ? wpi_fw_errmsg[dump.desc] : "UNKNOWN", dump.desc); printf(" error data = 0x%08X\n", dump.data); printf(" branch link = 0x%08X%08X\n", dump.blink[0], dump.blink[1]); printf(" interrupt link = 0x%08X%08X\n", dump.ilink[0], dump.ilink[1]); printf(" time = %u\n", dump.time); offset += sizeof (dump); } wpi_nic_unlock(sc); /* Dump driver status (TX and RX rings) while we're here. */ printf("driver status:\n"); for (i = 0; i < 6; i++) { struct wpi_tx_ring *ring = &sc->txq[i]; printf(" tx ring %2d: qid=%-2d cur=%-3d queued=%-3d\n", i, ring->qid, ring->cur, ring->queued); } printf(" rx ring: cur=%d\n", sc->rxq.cur); printf(" 802.11 state %d\n", sc->sc_ic.ic_state); #undef N } int wpi_intr(void *arg) { struct wpi_softc *sc = arg; struct ifnet *ifp = &sc->sc_ic.ic_if; uint32_t r1, r2; /* Disable interrupts. */ WPI_WRITE(sc, WPI_MASK, 0); r1 = WPI_READ(sc, WPI_INT); r2 = WPI_READ(sc, WPI_FH_INT); if (r1 == 0 && r2 == 0) { if (ifp->if_flags & IFF_UP) WPI_WRITE(sc, WPI_MASK, WPI_INT_MASK); return 0; /* Interrupt not for us. */ } if (r1 == 0xffffffff || (r1 & 0xfffffff0) == 0xa5a5a5a0) return 0; /* Hardware gone! */ /* Acknowledge interrupts. */ WPI_WRITE(sc, WPI_INT, r1); WPI_WRITE(sc, WPI_FH_INT, r2); if (r1 & (WPI_INT_SW_ERR | WPI_INT_HW_ERR)) { printf("%s: fatal firmware error\n", sc->sc_dev.dv_xname); /* Dump firmware error log and stop. */ wpi_fatal_intr(sc); ifp->if_flags &= ~IFF_UP; wpi_stop(ifp, 1); return 1; } if ((r1 & (WPI_INT_FH_RX | WPI_INT_SW_RX)) || (r2 & WPI_FH_INT_RX)) wpi_notif_intr(sc); if (r1 & WPI_INT_ALIVE) wakeup(sc); /* Firmware is alive. */ /* Re-enable interrupts. */ if (ifp->if_flags & IFF_UP) WPI_WRITE(sc, WPI_MASK, WPI_INT_MASK); return 1; } int wpi_tx(struct wpi_softc *sc, struct mbuf *m, struct ieee80211_node *ni) { struct ieee80211com *ic = &sc->sc_ic; struct wpi_node *wn = (void *)ni; struct wpi_tx_ring *ring; struct wpi_tx_desc *desc; struct wpi_tx_data *data; struct wpi_tx_cmd *cmd; struct wpi_cmd_data *tx; const struct wpi_rate *rinfo; struct ieee80211_frame *wh; struct ieee80211_key *k = NULL; struct mbuf *m1; enum ieee80211_edca_ac ac; uint32_t flags; uint16_t qos; u_int hdrlen; uint8_t *ivp, tid, ridx, type; int i, totlen, hasqos, error; wh = mtod(m, struct ieee80211_frame *); hdrlen = ieee80211_get_hdrlen(wh); type = wh->i_fc[0] & IEEE80211_FC0_TYPE_MASK; /* Select EDCA Access Category and TX ring for this frame. */ if ((hasqos = ieee80211_has_qos(wh))) { qos = ieee80211_get_qos(wh); tid = qos & IEEE80211_QOS_TID; ac = ieee80211_up_to_ac(ic, tid); } else { tid = 0; ac = EDCA_AC_BE; } ring = &sc->txq[ac]; desc = &ring->desc[ring->cur]; data = &ring->data[ring->cur]; /* Choose a TX rate index. */ if (IEEE80211_IS_MULTICAST(wh->i_addr1) || type != IEEE80211_FC0_TYPE_DATA) { ridx = (ic->ic_curmode == IEEE80211_MODE_11A) ? WPI_RIDX_OFDM6 : WPI_RIDX_CCK1; } else if (ic->ic_fixed_rate != -1) { ridx = sc->fixed_ridx; } else ridx = wn->ridx[ni->ni_txrate]; rinfo = &wpi_rates[ridx]; #if NBPFILTER > 0 if (sc->sc_drvbpf != NULL) { struct mbuf mb; struct wpi_tx_radiotap_header *tap = &sc->sc_txtap; tap->wt_flags = 0; tap->wt_chan_freq = htole16(ni->ni_chan->ic_freq); tap->wt_chan_flags = htole16(ni->ni_chan->ic_flags); tap->wt_rate = rinfo->rate; tap->wt_hwqueue = ac; if ((ic->ic_flags & IEEE80211_F_WEPON) && (wh->i_fc[1] & IEEE80211_FC1_PROTECTED)) tap->wt_flags |= IEEE80211_RADIOTAP_F_WEP; mb.m_data = (caddr_t)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_mtap(sc->sc_drvbpf, &mb, BPF_DIRECTION_OUT); } #endif totlen = m->m_pkthdr.len; /* Encrypt the frame if need be. */ if (wh->i_fc[1] & IEEE80211_FC1_PROTECTED) { /* Retrieve key for TX. */ k = ieee80211_get_txkey(ic, wh, ni); if (k->k_cipher != IEEE80211_CIPHER_CCMP) { /* Do software encryption. */ if ((m = ieee80211_encrypt(ic, m, k)) == NULL) return ENOBUFS; /* 802.11 header may have moved. */ wh = mtod(m, struct ieee80211_frame *); totlen = m->m_pkthdr.len; } else /* HW appends CCMP MIC. */ totlen += IEEE80211_CCMP_HDRLEN; } /* Prepare TX firmware command. */ cmd = &ring->cmd[ring->cur]; cmd->code = WPI_CMD_TX_DATA; cmd->flags = 0; cmd->qid = ring->qid; cmd->idx = ring->cur; tx = (struct wpi_cmd_data *)cmd->data; /* NB: No need to clear tx, all fields are reinitialized here. */ flags = 0; if (!IEEE80211_IS_MULTICAST(wh->i_addr1)) { /* Unicast frame, check if an ACK is expected. */ if (!hasqos || (qos & IEEE80211_QOS_ACK_POLICY_MASK) != IEEE80211_QOS_ACK_POLICY_NOACK) flags |= WPI_TX_NEED_ACK; } /* Check if frame must be protected using RTS/CTS or CTS-to-self. */ if (!IEEE80211_IS_MULTICAST(wh->i_addr1)) { /* NB: Group frames are sent using CCK in 802.11b/g. */ if (totlen + IEEE80211_CRC_LEN > ic->ic_rtsthreshold) { flags |= WPI_TX_NEED_RTS | WPI_TX_FULL_TXOP; } else if ((ic->ic_flags & IEEE80211_F_USEPROT) && ridx <= WPI_RIDX_OFDM54) { if (ic->ic_protmode == IEEE80211_PROT_CTSONLY) flags |= WPI_TX_NEED_CTS | WPI_TX_FULL_TXOP; else if (ic->ic_protmode == IEEE80211_PROT_RTSCTS) flags |= WPI_TX_NEED_RTS | WPI_TX_FULL_TXOP; } } if (IEEE80211_IS_MULTICAST(wh->i_addr1) || type != IEEE80211_FC0_TYPE_DATA) tx->id = WPI_ID_BROADCAST; else tx->id = wn->id; if (type == IEEE80211_FC0_TYPE_MGT) { uint8_t subtype = wh->i_fc[0] & IEEE80211_FC0_SUBTYPE_MASK; #ifndef IEEE80211_STA_ONLY /* Tell HW to set timestamp in probe responses. */ if (subtype == IEEE80211_FC0_SUBTYPE_PROBE_RESP) flags |= WPI_TX_INSERT_TSTAMP; #endif if (subtype == IEEE80211_FC0_SUBTYPE_ASSOC_REQ || subtype == IEEE80211_FC0_SUBTYPE_REASSOC_REQ) tx->timeout = htole16(3); else tx->timeout = htole16(2); } else tx->timeout = htole16(0); tx->len = htole16(totlen); tx->tid = tid; tx->rts_ntries = 7; tx->data_ntries = 15; tx->ofdm_mask = 0xff; tx->cck_mask = 0x0f; tx->lifetime = htole32(WPI_LIFETIME_INFINITE); tx->plcp = rinfo->plcp; /* Copy 802.11 header in TX command. */ memcpy((uint8_t *)(tx + 1), wh, hdrlen); if (k != NULL && k->k_cipher == IEEE80211_CIPHER_CCMP) { /* Trim 802.11 header and prepend CCMP IV. */ m_adj(m, hdrlen - IEEE80211_CCMP_HDRLEN); ivp = mtod(m, uint8_t *); k->k_tsc++; ivp[0] = k->k_tsc; ivp[1] = k->k_tsc >> 8; ivp[2] = 0; ivp[3] = k->k_id << 6 | IEEE80211_WEP_EXTIV; ivp[4] = k->k_tsc >> 16; ivp[5] = k->k_tsc >> 24; ivp[6] = k->k_tsc >> 32; ivp[7] = k->k_tsc >> 40; tx->security = WPI_CIPHER_CCMP; memcpy(tx->key, k->k_key, k->k_len); } else { /* Trim 802.11 header. */ m_adj(m, hdrlen); tx->security = 0; } tx->flags = htole32(flags); error = bus_dmamap_load_mbuf(sc->sc_dmat, data->map, m, BUS_DMA_NOWAIT); if (error != 0 && error != EFBIG) { printf("%s: can't map mbuf (error %d)\n", sc->sc_dev.dv_xname, error); m_freem(m); return error; } if (error != 0) { /* Too many DMA segments, linearize mbuf. */ MGETHDR(m1, M_DONTWAIT, MT_DATA); if (m1 == NULL) { m_freem(m); return ENOBUFS; } if (m->m_pkthdr.len > MHLEN) { MCLGET(m1, M_DONTWAIT); if (!(m1->m_flags & M_EXT)) { m_freem(m); m_freem(m1); return ENOBUFS; } } m_copydata(m, 0, m->m_pkthdr.len, mtod(m1, caddr_t)); m1->m_pkthdr.len = m1->m_len = m->m_pkthdr.len; m_freem(m); m = m1; error = bus_dmamap_load_mbuf(sc->sc_dmat, data->map, m, BUS_DMA_NOWAIT); if (error != 0) { printf("%s: can't map mbuf (error %d)\n", sc->sc_dev.dv_xname, error); m_freem(m); return error; } } data->m = m; data->ni = ni; DPRINTFN(4, ("sending data: qid=%d idx=%d len=%d nsegs=%d\n", ring->qid, ring->cur, m->m_pkthdr.len, data->map->dm_nsegs)); /* Fill TX descriptor. */ desc->flags = htole32(WPI_PAD32(m->m_pkthdr.len) << 28 | (1 + data->map->dm_nsegs) << 24); /* First DMA segment is used by the TX command. */ desc->segs[0].addr = htole32(ring->cmd_dma.paddr + ring->cur * sizeof (struct wpi_tx_cmd)); desc->segs[0].len = htole32(4 + sizeof (struct wpi_cmd_data) + ((hdrlen + 3) & ~3)); /* Other DMA segments are for data payload. */ for (i = 1; i <= data->map->dm_nsegs; i++) { desc->segs[i].addr = htole32(data->map->dm_segs[i - 1].ds_addr); desc->segs[i].len = htole32(data->map->dm_segs[i - 1].ds_len); } bus_dmamap_sync(sc->sc_dmat, data->map, 0, data->map->dm_mapsize, BUS_DMASYNC_PREWRITE); bus_dmamap_sync(sc->sc_dmat, ring->cmd_dma.map, (caddr_t)cmd - ring->cmd_dma.vaddr, sizeof (*cmd), BUS_DMASYNC_PREWRITE); bus_dmamap_sync(sc->sc_dmat, ring->desc_dma.map, (caddr_t)desc - ring->desc_dma.vaddr, sizeof (*desc), BUS_DMASYNC_PREWRITE); /* Kick TX ring. */ ring->cur = (ring->cur + 1) % WPI_TX_RING_COUNT; WPI_WRITE(sc, WPI_HBUS_TARG_WRPTR, ring->qid << 8 | ring->cur); /* Mark TX ring as full if we reach a certain threshold. */ if (++ring->queued > WPI_TX_RING_HIMARK) sc->qfullmsk |= 1 << ring->qid; return 0; } void wpi_start(struct ifnet *ifp) { struct wpi_softc *sc = ifp->if_softc; struct ieee80211com *ic = &sc->sc_ic; struct ieee80211_node *ni; struct mbuf *m; if ((ifp->if_flags & (IFF_RUNNING | IFF_OACTIVE)) != IFF_RUNNING) return; for (;;) { if (sc->qfullmsk != 0) { ifp->if_flags |= IFF_OACTIVE; break; } /* Send pending management frames first. */ IF_DEQUEUE(&ic->ic_mgtq, m); if (m != NULL) { ni = (void *)m->m_pkthdr.rcvif; goto sendit; } if (ic->ic_state != IEEE80211_S_RUN) break; /* Encapsulate and send data frames. */ IFQ_DEQUEUE(&ifp->if_snd, m); if (m == NULL) break; #if NBPFILTER > 0 if (ifp->if_bpf != NULL) bpf_mtap(ifp->if_bpf, m, BPF_DIRECTION_OUT); #endif if ((m = ieee80211_encap(ifp, m, &ni)) == NULL) continue; sendit: #if NBPFILTER > 0 if (ic->ic_rawbpf != NULL) bpf_mtap(ic->ic_rawbpf, m, BPF_DIRECTION_OUT); #endif if (wpi_tx(sc, m, ni) != 0) { ieee80211_release_node(ic, ni); ifp->if_oerrors++; continue; } sc->sc_tx_timer = 5; ifp->if_timer = 1; } } void wpi_watchdog(struct ifnet *ifp) { struct wpi_softc *sc = ifp->if_softc; ifp->if_timer = 0; if (sc->sc_tx_timer > 0) { if (--sc->sc_tx_timer == 0) { printf("%s: device timeout\n", sc->sc_dev.dv_xname); ifp->if_flags &= ~IFF_UP; wpi_stop(ifp, 1); ifp->if_oerrors++; return; } ifp->if_timer = 1; } ieee80211_watchdog(ifp); } int wpi_ioctl(struct ifnet *ifp, u_long cmd, caddr_t data) { struct wpi_softc *sc = ifp->if_softc; struct ieee80211com *ic = &sc->sc_ic; struct ifaddr *ifa; struct ifreq *ifr; int s, error = 0; s = splnet(); switch (cmd) { case SIOCSIFADDR: ifa = (struct ifaddr *)data; ifp->if_flags |= IFF_UP; #ifdef INET if (ifa->ifa_addr->sa_family == AF_INET) arp_ifinit(&ic->ic_ac, ifa); #endif /* FALLTHROUGH */ case SIOCSIFFLAGS: if (ifp->if_flags & IFF_UP) { if (!(ifp->if_flags & IFF_RUNNING)) error = wpi_init(ifp); } else { if (ifp->if_flags & IFF_RUNNING) wpi_stop(ifp, 1); } break; case SIOCADDMULTI: case SIOCDELMULTI: ifr = (struct ifreq *)data; error = (cmd == SIOCADDMULTI) ? ether_addmulti(ifr, &ic->ic_ac) : ether_delmulti(ifr, &ic->ic_ac); if (error == ENETRESET) error = 0; break; case SIOCS80211POWER: error = ieee80211_ioctl(ifp, cmd, data); if (error != ENETRESET) break; if (ic->ic_state == IEEE80211_S_RUN) { if (ic->ic_flags & IEEE80211_F_PMGTON) error = wpi_set_pslevel(sc, 0, 3, 0); else /* back to CAM */ error = wpi_set_pslevel(sc, 0, 0, 0); } else { /* Defer until transition to IEEE80211_S_RUN. */ error = 0; } break; default: error = ieee80211_ioctl(ifp, cmd, data); } if (error == ENETRESET) { error = 0; if ((ifp->if_flags & (IFF_UP | IFF_RUNNING)) == (IFF_UP | IFF_RUNNING)) { wpi_stop(ifp, 0); error = wpi_init(ifp); } } splx(s); return error; } /* * Send a command to the firmware. */ int wpi_cmd(struct wpi_softc *sc, int code, const void *buf, int size, int async) { struct wpi_tx_ring *ring = &sc->txq[4]; struct wpi_tx_desc *desc; struct wpi_tx_data *data; struct wpi_tx_cmd *cmd; struct mbuf *m; bus_addr_t paddr; int totlen, error; desc = &ring->desc[ring->cur]; data = &ring->data[ring->cur]; totlen = 4 + size; if (size > sizeof cmd->data) { /* Command is too large to fit in a descriptor. */ if (totlen > MCLBYTES) return EINVAL; MGETHDR(m, M_DONTWAIT, MT_DATA); if (m == NULL) return ENOMEM; if (totlen > MHLEN) { MCLGET(m, M_DONTWAIT); if (!(m->m_flags & M_EXT)) { m_freem(m); return ENOMEM; } } cmd = mtod(m, struct wpi_tx_cmd *); error = bus_dmamap_load(sc->sc_dmat, data->map, cmd, totlen, NULL, BUS_DMA_NOWAIT); if (error != 0) { m_freem(m); return error; } data->m = m; paddr = data->map->dm_segs[0].ds_addr; } else { cmd = &ring->cmd[ring->cur]; paddr = data->cmd_paddr; } cmd->code = code; cmd->flags = 0; cmd->qid = ring->qid; cmd->idx = ring->cur; memcpy(cmd->data, buf, size); desc->flags = htole32(WPI_PAD32(size) << 28 | 1 << 24); desc->segs[0].addr = htole32(paddr); desc->segs[0].len = htole32(totlen); if (size > sizeof cmd->data) { bus_dmamap_sync(sc->sc_dmat, data->map, 0, totlen, BUS_DMASYNC_PREWRITE); } else { bus_dmamap_sync(sc->sc_dmat, ring->cmd_dma.map, (caddr_t)cmd - ring->cmd_dma.vaddr, totlen, BUS_DMASYNC_PREWRITE); } bus_dmamap_sync(sc->sc_dmat, ring->desc_dma.map, (caddr_t)desc - ring->desc_dma.vaddr, sizeof (*desc), BUS_DMASYNC_PREWRITE); /* Kick command ring. */ ring->cur = (ring->cur + 1) % WPI_TX_RING_COUNT; WPI_WRITE(sc, WPI_HBUS_TARG_WRPTR, ring->qid << 8 | ring->cur); return async ? 0 : tsleep(cmd, PCATCH, "wpicmd", hz); } /* * Configure HW multi-rate retries. */ int wpi_mrr_setup(struct wpi_softc *sc) { struct ieee80211com *ic = &sc->sc_ic; struct wpi_mrr_setup mrr; int i, error; /* CCK rates (not used with 802.11a). */ for (i = WPI_RIDX_CCK1; i <= WPI_RIDX_CCK11; i++) { mrr.rates[i].flags = 0; mrr.rates[i].plcp = wpi_rates[i].plcp; /* Fallback to the immediate lower CCK rate (if any.) */ mrr.rates[i].next = (i == WPI_RIDX_CCK1) ? WPI_RIDX_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_RIDX_OFDM6; i <= WPI_RIDX_OFDM54; i++) { mrr.rates[i].flags = 0; mrr.rates[i].plcp = wpi_rates[i].plcp; /* Fallback to the immediate lower rate (if any.) */ /* We allow fallback from OFDM/6 to CCK/2 in 11b/g mode. */ mrr.rates[i].next = (i == WPI_RIDX_OFDM6) ? ((ic->ic_curmode == IEEE80211_MODE_11A) ? WPI_RIDX_OFDM6 : WPI_RIDX_CCK2) : 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 = htole32(WPI_MRR_CTL); error = wpi_cmd(sc, WPI_CMD_MRR_SETUP, &mrr, sizeof mrr, 0); if (error != 0) { printf("%s: could not setup MRR for control frames\n", sc->sc_dev.dv_xname); return error; } /* Setup MRR for data frames. */ mrr.which = htole32(WPI_MRR_DATA); error = wpi_cmd(sc, WPI_CMD_MRR_SETUP, &mrr, sizeof mrr, 0); if (error != 0) { printf("%s: could not setup MRR for data frames\n", sc->sc_dev.dv_xname); return error; } return 0; } void wpi_updateedca(struct ieee80211com *ic) { #define WPI_EXP2(x) ((1 << (x)) - 1) /* CWmin = 2^ECWmin - 1 */ struct wpi_softc *sc = ic->ic_softc; struct wpi_edca_params cmd; int aci; memset(&cmd, 0, sizeof cmd); cmd.flags = htole32(WPI_EDCA_UPDATE); for (aci = 0; aci < EDCA_NUM_AC; aci++) { const struct ieee80211_edca_ac_params *ac = &ic->ic_edca_ac[aci]; cmd.ac[aci].aifsn = ac->ac_aifsn; cmd.ac[aci].cwmin = htole16(WPI_EXP2(ac->ac_ecwmin)); cmd.ac[aci].cwmax = htole16(WPI_EXP2(ac->ac_ecwmax)); cmd.ac[aci].txoplimit = htole16(IEEE80211_TXOP_TO_US(ac->ac_txoplimit)); } (void)wpi_cmd(sc, WPI_CMD_EDCA_PARAMS, &cmd, sizeof cmd, 1); #undef WPI_EXP2 } void wpi_set_led(struct wpi_softc *sc, uint8_t which, uint8_t off, uint8_t on) { struct wpi_cmd_led led; led.which = which; led.unit = htole32(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); } int wpi_set_timing(struct wpi_softc *sc, struct ieee80211_node *ni) { struct wpi_cmd_timing cmd; uint64_t val, mod; memset(&cmd, 0, sizeof cmd); memcpy(&cmd.tstamp, ni->ni_tstamp, sizeof (uint64_t)); cmd.bintval = htole16(ni->ni_intval); cmd.lintval = htole16(10); /* Compute remaining time until next beacon. */ val = (uint64_t)ni->ni_intval * 1024; /* msecs -> usecs */ mod = letoh64(cmd.tstamp) % val; cmd.binitval = htole32((uint32_t)(val - mod)); DPRINTF(("timing bintval=%u, tstamp=%llu, init=%u\n", ni->ni_intval, letoh64(cmd.tstamp), (uint32_t)(val - mod))); return wpi_cmd(sc, WPI_CMD_TIMING, &cmd, sizeof cmd, 1); } /* * This function is called periodically (every minute) to adjust TX power * based on temperature variation. */ void wpi_power_calibration(struct wpi_softc *sc, int temp) { /* Sanity-check temperature. */ if (temp < -260 || temp > 25) { /* This can't be correct, ignore. */ DPRINTF(("out-of-range temperature reported: %d\n", temp)); return; } DPRINTF(("temperature %d->%d\n", sc->temp, temp)); /* Adjust TX power if need be (delta > 6). */ if (abs(temp - sc->temp) > 6) { /* Record temperature of last calibration. */ sc->temp = temp; (void)wpi_set_txpower(sc, 1); } } /* * Set TX power for current channel (each rate has its own power settings). */ int wpi_set_txpower(struct wpi_softc *sc, int async) { struct ieee80211com *ic = &sc->sc_ic; struct ieee80211_channel *ch; struct wpi_power_group *group; struct wpi_cmd_txpower cmd; u_int chan; int idx, i; /* Retrieve current channel from last RXON. */ chan = sc->rxon.chan; DPRINTF(("setting TX power for channel %d\n", chan)); ch = &ic->ic_channels[chan]; /* Find the TX power group to which this channel belongs. */ if (IEEE80211_IS_CHAN_5GHZ(ch)) { for (group = &sc->groups[1]; group < &sc->groups[4]; group++) if (chan <= group->chan) break; } else group = &sc->groups[0]; memset(&cmd, 0, sizeof cmd); cmd.band = IEEE80211_IS_CHAN_5GHZ(ch) ? 0 : 1; cmd.chan = htole16(chan); /* Set TX power for all OFDM and CCK rates. */ for (i = 0; i <= WPI_RIDX_MAX ; i++) { /* Retrieve TX power for this channel/rate. */ idx = wpi_get_power_index(sc, group, ch, i); cmd.rates[i].plcp = wpi_rates[i].plcp; if (IEEE80211_IS_CHAN_5GHZ(ch)) { cmd.rates[i].rf_gain = wpi_rf_gain_5ghz[idx]; cmd.rates[i].dsp_gain = wpi_dsp_gain_5ghz[idx]; } else { cmd.rates[i].rf_gain = wpi_rf_gain_2ghz[idx]; cmd.rates[i].dsp_gain = wpi_dsp_gain_2ghz[idx]; } DPRINTF(("chan %d/rate %d: power index %d\n", chan, wpi_rates[i].rate, idx)); } return wpi_cmd(sc, WPI_CMD_TXPOWER, &cmd, sizeof cmd, async); } /* * Determine TX power index for a given channel/rate combination. * This takes into account the regulatory information from EEPROM and the * current temperature. */ int wpi_get_power_index(struct wpi_softc *sc, struct wpi_power_group *group, struct ieee80211_channel *c, int ridx) { /* Fixed-point arithmetic division using a n-bit fractional part. */ #define fdivround(a, b, n) \ ((((1 << n) * (a)) / (b) + (1 << n) / 2) / (1 << n)) /* Linear interpolation. */ #define interpolate(x, x1, y1, x2, y2, n) \ ((y1) + fdivround(((x) - (x1)) * ((y2) - (y1)), (x2) - (x1), n)) struct ieee80211com *ic = &sc->sc_ic; struct wpi_power_sample *sample; int pwr, idx; u_int chan; /* Get channel number. */ chan = ieee80211_chan2ieee(ic, c); /* Default TX power is group's maximum TX power minus 3dB. */ pwr = group->maxpwr / 2; /* Decrease TX power for highest OFDM rates to reduce distortion. */ switch (ridx) { case WPI_RIDX_OFDM36: pwr -= IEEE80211_IS_CHAN_2GHZ(c) ? 0 : 5; break; case WPI_RIDX_OFDM48: pwr -= IEEE80211_IS_CHAN_2GHZ(c) ? 7 : 10; break; case WPI_RIDX_OFDM54: pwr -= IEEE80211_IS_CHAN_2GHZ(c) ? 9 : 12; break; } /* Never exceed the channel's maximum allowed TX power. */ pwr = MIN(pwr, sc->maxpwr[chan]); /* Retrieve TX power index into gain tables from samples. */ for (sample = group->samples; sample < &group->samples[3]; sample++) if (pwr > sample[1].power) break; /* Fixed-point linear interpolation using a 19-bit fractional part. */ idx = interpolate(pwr, sample[0].power, sample[0].index, sample[1].power, sample[1].index, 19); /*- * Adjust power index based on current temperature: * - if cooler than factory-calibrated: decrease output power * - if warmer than factory-calibrated: increase output power */ idx -= (sc->temp - group->temp) * 11 / 100; /* Decrease TX power for CCK rates (-5dB). */ if (ridx >= WPI_RIDX_CCK1) idx += 10; /* Make sure idx stays in a valid range. */ if (idx < 0) idx = 0; else if (idx > WPI_MAX_PWR_INDEX) idx = WPI_MAX_PWR_INDEX; return idx; #undef interpolate #undef fdivround } /* * Set STA mode power saving level (between 0 and 5). * Level 0 is CAM (Continuously Aware Mode), 5 is for maximum power saving. */ int wpi_set_pslevel(struct wpi_softc *sc, int dtim, int level, int async) { struct wpi_pmgt_cmd cmd; const struct wpi_pmgt *pmgt; uint32_t max, skip_dtim; pcireg_t reg; int i; /* Select which PS parameters to use. */ if (dtim <= 10) pmgt = &wpi_pmgt[0][level]; else pmgt = &wpi_pmgt[1][level]; memset(&cmd, 0, sizeof cmd); if (level != 0) /* not CAM */ cmd.flags |= htole16(WPI_PS_ALLOW_SLEEP); /* Retrieve PCIe Active State Power Management (ASPM). */ reg = pci_conf_read(sc->sc_pct, sc->sc_pcitag, sc->sc_cap_off + PCI_PCIE_LCSR); if (!(reg & PCI_PCIE_LCSR_ASPM_L0S)) /* L0s Entry disabled. */ cmd.flags |= htole16(WPI_PS_PCI_PMGT); cmd.rxtimeout = htole32(pmgt->rxtimeout * 1024); cmd.txtimeout = htole32(pmgt->txtimeout * 1024); if (dtim == 0) { dtim = 1; skip_dtim = 0; } else skip_dtim = pmgt->skip_dtim; if (skip_dtim != 0) { cmd.flags |= htole16(WPI_PS_SLEEP_OVER_DTIM); max = pmgt->intval[4]; if (max == (uint32_t)-1) max = dtim * (skip_dtim + 1); else if (max > dtim) max = (max / dtim) * dtim; } else max = dtim; for (i = 0; i < 5; i++) cmd.intval[i] = htole32(MIN(max, pmgt->intval[i])); DPRINTF(("setting power saving level to %d\n", level)); return wpi_cmd(sc, WPI_CMD_SET_POWER_MODE, &cmd, sizeof cmd, async); } int wpi_config(struct wpi_softc *sc) { struct ieee80211com *ic = &sc->sc_ic; struct ifnet *ifp = &ic->ic_if; struct wpi_bluetooth bluetooth; struct wpi_node_info node; int error; /* Set power saving level to CAM during initialization. */ if ((error = wpi_set_pslevel(sc, 0, 0, 0)) != 0) { printf("%s: could not set power saving level\n", sc->sc_dev.dv_xname); return error; } /* Configure bluetooth coexistence. */ memset(&bluetooth, 0, sizeof bluetooth); bluetooth.flags = 3; bluetooth.lead = 0xaa; bluetooth.kill = 1; error = wpi_cmd(sc, WPI_CMD_BT_COEX, &bluetooth, sizeof bluetooth, 0); if (error != 0) { printf("%s: could not configure bluetooth coexistence\n", sc->sc_dev.dv_xname); return error; } /* Configure adapter. */ memset(&sc->rxon, 0, sizeof (struct wpi_rxon)); IEEE80211_ADDR_COPY(ic->ic_myaddr, LLADDR(ifp->if_sadl)); IEEE80211_ADDR_COPY(sc->rxon.myaddr, ic->ic_myaddr); /* Set default channel. */ sc->rxon.chan = ieee80211_chan2ieee(ic, ic->ic_ibss_chan); sc->rxon.flags = htole32(WPI_RXON_TSF); if (IEEE80211_IS_CHAN_2GHZ(ic->ic_ibss_chan)) sc->rxon.flags |= htole32(WPI_RXON_AUTO | WPI_RXON_24GHZ); switch (ic->ic_opmode) { case IEEE80211_M_STA: sc->rxon.mode = WPI_MODE_STA; sc->rxon.filter = htole32(WPI_FILTER_MULTICAST); break; case IEEE80211_M_MONITOR: sc->rxon.mode = WPI_MODE_MONITOR; sc->rxon.filter = htole32(WPI_FILTER_MULTICAST | WPI_FILTER_CTL | WPI_FILTER_PROMISC); break; default: /* Should not get there. */ break; } sc->rxon.cck_mask = 0x0f; /* not yet negotiated */ sc->rxon.ofdm_mask = 0xff; /* not yet negotiated */ DPRINTF(("setting configuration\n")); error = wpi_cmd(sc, WPI_CMD_CONFIGURE, &sc->rxon, sizeof (struct wpi_rxon), 0); if (error != 0) { printf("%s: configure command failed\n", sc->sc_dev.dv_xname); return error; } /* Configuration has changed, set TX power accordingly. */ if ((error = wpi_set_txpower(sc, 0)) != 0) { printf("%s: could not set TX power\n", sc->sc_dev.dv_xname); return error; } /* Add broadcast node. */ memset(&node, 0, sizeof node); IEEE80211_ADDR_COPY(node.macaddr, etherbroadcastaddr); node.id = WPI_ID_BROADCAST; node.plcp = wpi_rates[WPI_RIDX_CCK1].plcp; node.action = htole32(WPI_ACTION_SET_RATE); node.antenna = WPI_ANTENNA_BOTH; error = wpi_cmd(sc, WPI_CMD_ADD_NODE, &node, sizeof node, 0); if (error != 0) { printf("%s: could not add broadcast node\n", sc->sc_dev.dv_xname); return error; } if ((error = wpi_mrr_setup(sc)) != 0) { printf("%s: could not setup MRR\n", sc->sc_dev.dv_xname); return error; } return 0; } int wpi_scan(struct wpi_softc *sc, uint16_t flags) { struct ieee80211com *ic = &sc->sc_ic; struct wpi_scan_hdr *hdr; struct wpi_cmd_data *tx; struct wpi_scan_essid *essid; struct wpi_scan_chan *chan; struct ieee80211_frame *wh; struct ieee80211_rateset *rs; struct ieee80211_channel *c; uint8_t *buf, *frm; int buflen, error; buf = malloc(WPI_SCAN_MAXSZ, M_DEVBUF, M_NOWAIT | M_ZERO); if (buf == NULL) { printf("%s: could not allocate buffer for scan command\n", sc->sc_dev.dv_xname); return ENOMEM; } hdr = (struct wpi_scan_hdr *)buf; /* * Move to the next channel if no frames are received within 10ms * after sending the probe request. */ hdr->quiet_time = htole16(10); /* timeout in milliseconds */ hdr->quiet_threshold = htole16(1); /* min # of packets */ tx = (struct wpi_cmd_data *)(hdr + 1); tx->flags = htole32(WPI_TX_AUTO_SEQ); tx->id = WPI_ID_BROADCAST; tx->lifetime = htole32(WPI_LIFETIME_INFINITE); if (flags & IEEE80211_CHAN_5GHZ) { hdr->crc_threshold = htole16(1); /* Send probe requests at 6Mbps. */ tx->plcp = wpi_rates[WPI_RIDX_OFDM6].plcp; rs = &ic->ic_sup_rates[IEEE80211_MODE_11A]; } else { hdr->flags = htole32(WPI_RXON_24GHZ | WPI_RXON_AUTO); /* Send probe requests at 1Mbps. */ tx->plcp = wpi_rates[WPI_RIDX_CCK1].plcp; rs = &ic->ic_sup_rates[IEEE80211_MODE_11G]; } essid = (struct wpi_scan_essid *)(tx + 1); if (ic->ic_des_esslen != 0) { essid[0].id = IEEE80211_ELEMID_SSID; essid[0].len = ic->ic_des_esslen; memcpy(essid[0].data, ic->ic_des_essid, ic->ic_des_esslen); } /* * Build a probe request frame. Most of the following code is a * copy & paste of what is done in net80211. */ wh = (struct ieee80211_frame *)(essid + 4); 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; IEEE80211_ADDR_COPY(wh->i_addr1, etherbroadcastaddr); IEEE80211_ADDR_COPY(wh->i_addr2, ic->ic_myaddr); IEEE80211_ADDR_COPY(wh->i_addr3, etherbroadcastaddr); *(uint16_t *)&wh->i_dur[0] = 0; /* filled by HW */ *(uint16_t *)&wh->i_seq[0] = 0; /* filled by HW */ frm = (uint8_t *)(wh + 1); frm = ieee80211_add_ssid(frm, NULL, 0); frm = ieee80211_add_rates(frm, rs); if (rs->rs_nrates > IEEE80211_RATE_SIZE) frm = ieee80211_add_xrates(frm, rs); /* Set length of probe request. */ tx->len = htole16(frm - (uint8_t *)wh); chan = (struct wpi_scan_chan *)frm; for (c = &ic->ic_channels[1]; c <= &ic->ic_channels[IEEE80211_CHAN_MAX]; c++) { if ((c->ic_flags & flags) != flags) continue; chan->chan = ieee80211_chan2ieee(ic, c); DPRINTFN(2, ("adding channel %d\n", chan->chan)); chan->flags = 0; if (!(c->ic_flags & IEEE80211_CHAN_PASSIVE)) chan->flags |= WPI_CHAN_ACTIVE; if (ic->ic_des_esslen != 0) chan->flags |= WPI_CHAN_NPBREQS(1); chan->dsp_gain = 0x6e; if (IEEE80211_IS_CHAN_5GHZ(c)) { chan->rf_gain = 0x3b; chan->active = htole16(24); chan->passive = htole16(110); } else { chan->rf_gain = 0x28; chan->active = htole16(36); chan->passive = htole16(120); } hdr->nchan++; chan++; } buflen = (uint8_t *)chan - buf; hdr->len = htole16(buflen); DPRINTF(("sending scan command nchan=%d\n", hdr->nchan)); error = wpi_cmd(sc, WPI_CMD_SCAN, buf, buflen, 1); free(buf, M_DEVBUF); return error; } int wpi_auth(struct wpi_softc *sc) { struct ieee80211com *ic = &sc->sc_ic; struct ieee80211_node *ni = ic->ic_bss; struct wpi_node_info node; int error; /* Update adapter's configuration. */ IEEE80211_ADDR_COPY(sc->rxon.bssid, ni->ni_bssid); sc->rxon.chan = ieee80211_chan2ieee(ic, ni->ni_chan); sc->rxon.flags = htole32(WPI_RXON_TSF); if (IEEE80211_IS_CHAN_2GHZ(ni->ni_chan)) sc->rxon.flags |= htole32(WPI_RXON_AUTO | WPI_RXON_24GHZ); if (ic->ic_flags & IEEE80211_F_SHSLOT) sc->rxon.flags |= htole32(WPI_RXON_SHSLOT); if (ic->ic_flags & IEEE80211_F_SHPREAMBLE) sc->rxon.flags |= htole32(WPI_RXON_SHPREAMBLE); switch (ic->ic_curmode) { case IEEE80211_MODE_11A: sc->rxon.cck_mask = 0; sc->rxon.ofdm_mask = 0x15; break; case IEEE80211_MODE_11B: sc->rxon.cck_mask = 0x03; sc->rxon.ofdm_mask = 0; break; default: /* Assume 802.11b/g. */ sc->rxon.cck_mask = 0x0f; sc->rxon.ofdm_mask = 0x15; } DPRINTF(("rxon chan %d flags %x cck %x ofdm %x\n", sc->rxon.chan, sc->rxon.flags, sc->rxon.cck_mask, sc->rxon.ofdm_mask)); error = wpi_cmd(sc, WPI_CMD_CONFIGURE, &sc->rxon, sizeof (struct wpi_rxon), 1); if (error != 0) { printf("%s: could not configure\n", sc->sc_dev.dv_xname); return error; } /* Configuration has changed, set TX power accordingly. */ if ((error = wpi_set_txpower(sc, 1)) != 0) { printf("%s: could not set TX power\n", sc->sc_dev.dv_xname); return error; } /* * Reconfiguring RXON clears the firmware's nodes table so we must * add the broadcast node again. */ memset(&node, 0, sizeof node); IEEE80211_ADDR_COPY(node.macaddr, etherbroadcastaddr); node.id = WPI_ID_BROADCAST; node.plcp = (ic->ic_curmode == IEEE80211_MODE_11A) ? wpi_rates[WPI_RIDX_OFDM6].plcp : wpi_rates[WPI_RIDX_CCK1].plcp; node.action = htole32(WPI_ACTION_SET_RATE); node.antenna = WPI_ANTENNA_BOTH; error = wpi_cmd(sc, WPI_CMD_ADD_NODE, &node, sizeof node, 1); if (error != 0) { printf("%s: could not add broadcast node\n", sc->sc_dev.dv_xname); return error; } return 0; } int wpi_run(struct wpi_softc *sc) { struct ieee80211com *ic = &sc->sc_ic; struct ieee80211_node *ni = ic->ic_bss; struct wpi_node_info node; int error; if (ic->ic_opmode == IEEE80211_M_MONITOR) { /* Link LED blinks while monitoring. */ wpi_set_led(sc, WPI_LED_LINK, 5, 5); return 0; } if ((error = wpi_set_timing(sc, ni)) != 0) { printf("%s: could not set timing\n", sc->sc_dev.dv_xname); return error; } /* Update adapter's configuration. */ sc->rxon.associd = htole16(IEEE80211_AID(ni->ni_associd)); /* Short preamble and slot time are negotiated when associating. */ sc->rxon.flags &= ~htole32(WPI_RXON_SHPREAMBLE | WPI_RXON_SHSLOT); if (ic->ic_flags & IEEE80211_F_SHSLOT) sc->rxon.flags |= htole32(WPI_RXON_SHSLOT); if (ic->ic_flags & IEEE80211_F_SHPREAMBLE) sc->rxon.flags |= htole32(WPI_RXON_SHPREAMBLE); sc->rxon.filter |= htole32(WPI_FILTER_BSS); DPRINTF(("rxon chan %d flags %x\n", sc->rxon.chan, sc->rxon.flags)); error = wpi_cmd(sc, WPI_CMD_CONFIGURE, &sc->rxon, sizeof (struct wpi_rxon), 1); if (error != 0) { printf("%s: could not update configuration\n", sc->sc_dev.dv_xname); return error; } /* Configuration has changed, set TX power accordingly. */ if ((error = wpi_set_txpower(sc, 1)) != 0) { printf("%s: could not set TX power\n", sc->sc_dev.dv_xname); return error; } /* Fake a join to init the TX rate. */ ((struct wpi_node *)ni)->id = WPI_ID_BSS; wpi_newassoc(ic, ni, 1); /* Add BSS node. */ memset(&node, 0, sizeof node); IEEE80211_ADDR_COPY(node.macaddr, ni->ni_bssid); node.id = WPI_ID_BSS; node.plcp = (ic->ic_curmode == IEEE80211_MODE_11A) ? wpi_rates[WPI_RIDX_OFDM6].plcp : wpi_rates[WPI_RIDX_CCK1].plcp; node.action = htole32(WPI_ACTION_SET_RATE); node.antenna = WPI_ANTENNA_BOTH; DPRINTF(("adding BSS node\n")); error = wpi_cmd(sc, WPI_CMD_ADD_NODE, &node, sizeof node, 1); if (error != 0) { printf("%s: could not add BSS node\n", sc->sc_dev.dv_xname); return error; } /* Start periodic calibration timer. */ sc->calib_cnt = 0; timeout_add(&sc->calib_to, hz / 2); /* Link LED always on while associated. */ wpi_set_led(sc, WPI_LED_LINK, 0, 1); /* Enable power-saving mode if requested by user. */ if (sc->sc_ic.ic_flags & IEEE80211_F_PMGTON) (void)wpi_set_pslevel(sc, 0, 3, 1); return 0; } /* * We support CCMP hardware encryption/decryption of unicast frames only. * HW support for TKIP really sucks. We should let TKIP die anyway. */ int wpi_set_key(struct ieee80211com *ic, struct ieee80211_node *ni, struct ieee80211_key *k) { struct wpi_softc *sc = ic->ic_softc; struct wpi_node *wn = (void *)ni; struct wpi_node_info node; uint16_t kflags; if ((k->k_flags & IEEE80211_KEY_GROUP) || k->k_cipher != IEEE80211_CIPHER_CCMP) return ieee80211_set_key(ic, ni, k); kflags = WPI_KFLAG_CCMP | WPI_KFLAG_KID(k->k_id); memset(&node, 0, sizeof node); node.id = wn->id; node.control = WPI_NODE_UPDATE; node.flags = WPI_FLAG_SET_KEY; node.kflags = htole16(kflags); memcpy(node.key, k->k_key, k->k_len); DPRINTF(("set key id=%d for node %d\n", k->k_id, node.id)); return wpi_cmd(sc, WPI_CMD_ADD_NODE, &node, sizeof node, 1); } void wpi_delete_key(struct ieee80211com *ic, struct ieee80211_node *ni, struct ieee80211_key *k) { struct wpi_softc *sc = ic->ic_softc; struct wpi_node *wn = (void *)ni; struct wpi_node_info node; if ((k->k_flags & IEEE80211_KEY_GROUP) || k->k_cipher != IEEE80211_CIPHER_CCMP) { /* See comment about other ciphers above. */ ieee80211_delete_key(ic, ni, k); return; } if (ic->ic_state != IEEE80211_S_RUN) return; /* Nothing to do. */ memset(&node, 0, sizeof node); node.id = wn->id; node.control = WPI_NODE_UPDATE; node.flags = WPI_FLAG_SET_KEY; node.kflags = 0; DPRINTF(("delete keys for node %d\n", node.id)); (void)wpi_cmd(sc, WPI_CMD_ADD_NODE, &node, sizeof node, 1); } int wpi_post_alive(struct wpi_softc *sc) { int ntries, error; /* Check (again) that the radio is not disabled. */ if ((error = wpi_nic_lock(sc)) != 0) return error; /* NB: Runtime firmware must be up and running. */ if (!(wpi_prph_read(sc, WPI_APMG_RFKILL) & 1)) { printf("%s: radio is disabled by hardware switch\n", sc->sc_dev.dv_xname); wpi_nic_unlock(sc); return EPERM; /* :-) */ } wpi_nic_unlock(sc); /* Wait for thermal sensor to calibrate. */ for (ntries = 0; ntries < 1000; ntries++) { if ((sc->temp = (int)WPI_READ(sc, WPI_UCODE_GP2)) != 0) break; DELAY(10); } if (ntries == 1000) { printf("%s: timeout waiting for thermal sensor calibration\n", sc->sc_dev.dv_xname); return ETIMEDOUT; } DPRINTF(("temperature %d\n", sc->temp)); sc->sensor.value = sc->temp + 260; sc->sensor.flags &= ~SENSOR_FINVALID; return 0; } /* * The firmware boot code is small and is intended to be copied directly into * the NIC internal memory (no DMA transfer.) */ int wpi_load_bootcode(struct wpi_softc *sc, const uint8_t *ucode, int size) { int error, ntries; size /= sizeof (uint32_t); if ((error = wpi_nic_lock(sc)) != 0) return error; /* Copy microcode image into NIC memory. */ wpi_prph_write_region_4(sc, WPI_BSM_SRAM_BASE, (const uint32_t *)ucode, size); wpi_prph_write(sc, WPI_BSM_WR_MEM_SRC, 0); wpi_prph_write(sc, WPI_BSM_WR_MEM_DST, WPI_FW_TEXT_BASE); wpi_prph_write(sc, WPI_BSM_WR_DWCOUNT, size); /* Start boot load now. */ wpi_prph_write(sc, WPI_BSM_WR_CTRL, WPI_BSM_WR_CTRL_START); /* Wait for transfer to complete. */ for (ntries = 0; ntries < 1000; ntries++) { if (!(wpi_prph_read(sc, WPI_BSM_WR_CTRL) & WPI_BSM_WR_CTRL_START)) break; DELAY(10); } if (ntries == 1000) { printf("%s: could not load boot firmware\n", sc->sc_dev.dv_xname); wpi_nic_unlock(sc); return ETIMEDOUT; } /* Enable boot after power up. */ wpi_prph_write(sc, WPI_BSM_WR_CTRL, WPI_BSM_WR_CTRL_START_EN); wpi_nic_unlock(sc); return 0; } int wpi_load_firmware(struct wpi_softc *sc) { struct wpi_fw_info *fw = &sc->fw; struct wpi_dma_info *dma = &sc->fw_dma; int error; /* Copy initialization sections into pre-allocated DMA-safe memory. */ memcpy(dma->vaddr, fw->init.data, fw->init.datasz); bus_dmamap_sync(sc->sc_dmat, dma->map, 0, fw->init.datasz, BUS_DMASYNC_PREWRITE); memcpy(dma->vaddr + WPI_FW_DATA_MAXSZ, fw->init.text, fw->init.textsz); bus_dmamap_sync(sc->sc_dmat, dma->map, WPI_FW_DATA_MAXSZ, fw->init.textsz, BUS_DMASYNC_PREWRITE); /* Tell adapter where to find initialization sections. */ if ((error = wpi_nic_lock(sc)) != 0) return error; wpi_prph_write(sc, WPI_BSM_DRAM_DATA_ADDR, dma->paddr); wpi_prph_write(sc, WPI_BSM_DRAM_DATA_SIZE, fw->init.datasz); wpi_prph_write(sc, WPI_BSM_DRAM_TEXT_ADDR, dma->paddr + WPI_FW_DATA_MAXSZ); wpi_prph_write(sc, WPI_BSM_DRAM_TEXT_SIZE, fw->init.textsz); wpi_nic_unlock(sc); /* Load firmware boot code. */ error = wpi_load_bootcode(sc, fw->boot.text, fw->boot.textsz); if (error != 0) { printf("%s: could not load boot firmware\n", sc->sc_dev.dv_xname); return error; } /* Now press "execute". */ WPI_WRITE(sc, WPI_RESET, 0); /* Wait at most one second for first alive notification. */ if ((error = tsleep(sc, PCATCH, "wpiinit", hz)) != 0) { printf("%s: timeout waiting for adapter to initialize\n", sc->sc_dev.dv_xname); return error; } /* Copy runtime sections into pre-allocated DMA-safe memory. */ memcpy(dma->vaddr, fw->main.data, fw->main.datasz); bus_dmamap_sync(sc->sc_dmat, dma->map, 0, fw->main.datasz, BUS_DMASYNC_PREWRITE); memcpy(dma->vaddr + WPI_FW_DATA_MAXSZ, fw->main.text, fw->main.textsz); bus_dmamap_sync(sc->sc_dmat, dma->map, WPI_FW_DATA_MAXSZ, fw->main.textsz, BUS_DMASYNC_PREWRITE); /* Tell adapter where to find runtime sections. */ if ((error = wpi_nic_lock(sc)) != 0) return error; wpi_prph_write(sc, WPI_BSM_DRAM_DATA_ADDR, dma->paddr); wpi_prph_write(sc, WPI_BSM_DRAM_DATA_SIZE, fw->main.datasz); wpi_prph_write(sc, WPI_BSM_DRAM_TEXT_ADDR, dma->paddr + WPI_FW_DATA_MAXSZ); wpi_prph_write(sc, WPI_BSM_DRAM_TEXT_SIZE, WPI_FW_UPDATED | fw->main.textsz); wpi_nic_unlock(sc); return 0; } int wpi_read_firmware(struct wpi_softc *sc) { struct wpi_fw_info *fw = &sc->fw; const struct wpi_firmware_hdr *hdr; size_t size; int error; /* Read firmware image from filesystem. */ if ((error = loadfirmware("wpi-3945abg", &fw->data, &size)) != 0) { printf("%s: error, %d, could not read firmware %s\n", sc->sc_dev.dv_xname, error, "wpi-3945abg"); return error; } if (size < sizeof (*hdr)) { printf("%s: truncated firmware header: %d bytes\n", sc->sc_dev.dv_xname, size); free(fw->data, M_DEVBUF); return EINVAL; } /* Extract firmware header information. */ hdr = (struct wpi_firmware_hdr *)fw->data; fw->main.textsz = letoh32(hdr->main_textsz); fw->main.datasz = letoh32(hdr->main_datasz); fw->init.textsz = letoh32(hdr->init_textsz); fw->init.datasz = letoh32(hdr->init_datasz); fw->boot.textsz = letoh32(hdr->boot_textsz); fw->boot.datasz = 0; /* Sanity-check firmware header. */ if (fw->main.textsz > WPI_FW_TEXT_MAXSZ || fw->main.datasz > WPI_FW_DATA_MAXSZ || fw->init.textsz > WPI_FW_TEXT_MAXSZ || fw->init.datasz > WPI_FW_DATA_MAXSZ || fw->boot.textsz > WPI_FW_BOOT_TEXT_MAXSZ || (fw->boot.textsz & 3) != 0) { printf("%s: invalid firmware header\n", sc->sc_dev.dv_xname); free(fw->data, M_DEVBUF); return EINVAL; } /* Check that all firmware sections fit. */ if (size < sizeof (*hdr) + fw->main.textsz + fw->main.datasz + fw->init.textsz + fw->init.datasz + fw->boot.textsz) { printf("%s: firmware file too short: %d bytes\n", sc->sc_dev.dv_xname, size); free(fw->data, M_DEVBUF); return EINVAL; } /* Get pointers to firmware sections. */ fw->main.text = (const uint8_t *)(hdr + 1); fw->main.data = fw->main.text + fw->main.textsz; fw->init.text = fw->main.data + fw->main.datasz; fw->init.data = fw->init.text + fw->init.textsz; fw->boot.text = fw->init.data + fw->init.datasz; return 0; } int wpi_clock_wait(struct wpi_softc *sc) { int ntries; /* Set "initialization complete" bit. */ WPI_SETBITS(sc, WPI_GP_CNTRL, WPI_GP_CNTRL_INIT_DONE); /* Wait for clock stabilization. */ for (ntries = 0; ntries < 25000; ntries++) { if (WPI_READ(sc, WPI_GP_CNTRL) & WPI_GP_CNTRL_MAC_CLOCK_READY) return 0; DELAY(100); } printf("%s: timeout waiting for clock stabilization\n", sc->sc_dev.dv_xname); return ETIMEDOUT; } int wpi_apm_init(struct wpi_softc *sc) { int error; WPI_SETBITS(sc, WPI_ANA_PLL, WPI_ANA_PLL_INIT); /* Disable L0s. */ WPI_SETBITS(sc, WPI_GIO_CHICKEN, WPI_GIO_CHICKEN_L1A_NO_L0S_RX); if ((error = wpi_clock_wait(sc)) != 0) return error; if ((error = wpi_nic_lock(sc)) != 0) return error; /* Enable DMA. */ wpi_prph_write(sc, WPI_APMG_CLK_ENA, WPI_APMG_CLK_DMA_CLK_RQT | WPI_APMG_CLK_BSM_CLK_RQT); DELAY(20); /* Disable L1. */ wpi_prph_setbits(sc, WPI_APMG_PCI_STT, WPI_APMG_PCI_STT_L1A_DIS); wpi_nic_unlock(sc); return 0; } void wpi_apm_stop_master(struct wpi_softc *sc) { int ntries; WPI_SETBITS(sc, WPI_RESET, WPI_RESET_STOP_MASTER); if ((WPI_READ(sc, WPI_GP_CNTRL) & WPI_GP_CNTRL_PS_MASK) == WPI_GP_CNTRL_MAC_PS) return; /* Already asleep. */ for (ntries = 0; ntries < 100; ntries++) { if (WPI_READ(sc, WPI_RESET) & WPI_RESET_MASTER_DISABLED) return; DELAY(10); } printf("%s: timeout waiting for master\n", sc->sc_dev.dv_xname); } void wpi_apm_stop(struct wpi_softc *sc) { wpi_apm_stop_master(sc); WPI_SETBITS(sc, WPI_RESET, WPI_RESET_SW); } void wpi_nic_config(struct wpi_softc *sc) { pcireg_t reg; uint8_t rev; /* Voodoo from the reference driver. */ reg = pci_conf_read(sc->sc_pct, sc->sc_pcitag, PCI_CLASS_REG); rev = PCI_REVISION(reg); if ((rev & 0xc0) == 0x40) WPI_SETBITS(sc, WPI_HW_IF_CONFIG, WPI_HW_IF_CONFIG_ALM_MB); else if (!(rev & 0x80)) WPI_SETBITS(sc, WPI_HW_IF_CONFIG, WPI_HW_IF_CONFIG_ALM_MM); if (sc->cap == 0x80) WPI_SETBITS(sc, WPI_HW_IF_CONFIG, WPI_HW_IF_CONFIG_SKU_MRC); if ((letoh16(sc->rev) & 0xf0) == 0xd0) WPI_SETBITS(sc, WPI_HW_IF_CONFIG, WPI_HW_IF_CONFIG_REV_D); else WPI_CLRBITS(sc, WPI_HW_IF_CONFIG, WPI_HW_IF_CONFIG_REV_D); if (sc->type > 1) WPI_SETBITS(sc, WPI_HW_IF_CONFIG, WPI_HW_IF_CONFIG_TYPE_B); } int wpi_hw_init(struct wpi_softc *sc) { int chnl, ntries, error; /* Clear pending interrupts. */ WPI_WRITE(sc, WPI_INT, 0xffffffff); if ((error = wpi_apm_init(sc)) != 0) { printf("%s: could not power ON adapter\n", sc->sc_dev.dv_xname); return error; } /* Select VMAIN power source. */ if ((error = wpi_nic_lock(sc)) != 0) return error; wpi_prph_clrbits(sc, WPI_APMG_PS, WPI_APMG_PS_PWR_SRC_MASK); wpi_nic_unlock(sc); /* Spin until VMAIN gets selected. */ for (ntries = 0; ntries < 5000; ntries++) { if (WPI_READ(sc, WPI_GPIO_IN) & WPI_GPIO_IN_VMAIN) break; DELAY(10); } if (ntries == 5000) { printf("%s: timeout selecting power source\n", sc->sc_dev.dv_xname); return ETIMEDOUT; } /* Perform adapter initialization. */ (void)wpi_nic_config(sc); /* Initialize RX ring. */ if ((error = wpi_nic_lock(sc)) != 0) return error; /* Set physical address of RX ring. */ WPI_WRITE(sc, WPI_FH_RX_BASE, sc->rxq.desc_dma.paddr); /* Set physical address of RX read pointer. */ WPI_WRITE(sc, WPI_FH_RX_RPTR_ADDR, sc->shared_dma.paddr + offsetof(struct wpi_shared, next)); WPI_WRITE(sc, WPI_FH_RX_WPTR, 0); /* Enable RX. */ WPI_WRITE(sc, WPI_FH_RX_CONFIG, WPI_FH_RX_CONFIG_DMA_ENA | WPI_FH_RX_CONFIG_RDRBD_ENA | WPI_FH_RX_CONFIG_WRSTATUS_ENA | WPI_FH_RX_CONFIG_MAXFRAG | WPI_FH_RX_CONFIG_NRBD(WPI_RX_RING_COUNT_LOG) | WPI_FH_RX_CONFIG_IRQ_DST_HOST | WPI_FH_RX_CONFIG_IRQ_RBTH(1)); (void)WPI_READ(sc, WPI_FH_RSSR_TBL); /* barrier */ WPI_WRITE(sc, WPI_FH_RX_WPTR, (WPI_RX_RING_COUNT - 1) & ~7); wpi_nic_unlock(sc); /* Initialize TX rings. */ if ((error = wpi_nic_lock(sc)) != 0) return error; wpi_prph_write(sc, WPI_ALM_SCHED_MODE, 2); /* bypass mode */ wpi_prph_write(sc, WPI_ALM_SCHED_ARASTAT, 1); /* enable RA0 */ /* Enable all 6 TX rings. */ wpi_prph_write(sc, WPI_ALM_SCHED_TXFACT, 0x3f); wpi_prph_write(sc, WPI_ALM_SCHED_SBYPASS_MODE1, 0x10000); wpi_prph_write(sc, WPI_ALM_SCHED_SBYPASS_MODE2, 0x30002); wpi_prph_write(sc, WPI_ALM_SCHED_TXF4MF, 4); wpi_prph_write(sc, WPI_ALM_SCHED_TXF5MF, 5); /* Set physical address of TX rings. */ WPI_WRITE(sc, WPI_FH_TX_BASE, sc->shared_dma.paddr); WPI_WRITE(sc, WPI_FH_MSG_CONFIG, 0xffff05a5); /* Enable all DMA channels. */ for (chnl = 0; chnl < WPI_NDMACHNLS; chnl++) { WPI_WRITE(sc, WPI_FH_CBBC_CTRL(chnl), 0); WPI_WRITE(sc, WPI_FH_CBBC_BASE(chnl), 0); WPI_WRITE(sc, WPI_FH_TX_CONFIG(chnl), 0x80200008); } wpi_nic_unlock(sc); (void)WPI_READ(sc, WPI_FH_TX_BASE); /* barrier */ /* Clear "radio off" and "commands blocked" bits. */ WPI_WRITE(sc, WPI_UCODE_GP1_CLR, WPI_UCODE_GP1_RFKILL); WPI_WRITE(sc, WPI_UCODE_GP1_CLR, WPI_UCODE_GP1_CMD_BLOCKED); /* Clear pending interrupts. */ WPI_WRITE(sc, WPI_INT, 0xffffffff); /* Enable interrupts. */ WPI_WRITE(sc, WPI_MASK, WPI_INT_MASK); /* _Really_ make sure "radio off" bit is cleared! */ WPI_WRITE(sc, WPI_UCODE_GP1_CLR, WPI_UCODE_GP1_RFKILL); WPI_WRITE(sc, WPI_UCODE_GP1_CLR, WPI_UCODE_GP1_RFKILL); if ((error = wpi_load_firmware(sc)) != 0) { printf("%s: could not load firmware\n", sc->sc_dev.dv_xname); return error; } /* Wait at most one second for firmware alive notification. */ if ((error = tsleep(sc, PCATCH, "wpiinit", hz)) != 0) { printf("%s: timeout waiting for adapter to initialize\n", sc->sc_dev.dv_xname); return error; } /* Do post-firmware initialization. */ return wpi_post_alive(sc); } void wpi_hw_stop(struct wpi_softc *sc) { int chnl, qid, ntries; uint32_t tmp; WPI_WRITE(sc, WPI_RESET, WPI_RESET_NEVO); /* Disable interrupts. */ WPI_WRITE(sc, WPI_MASK, 0); WPI_WRITE(sc, WPI_INT, 0xffffffff); WPI_WRITE(sc, WPI_FH_INT, 0xffffffff); /* Make sure we no longer hold the NIC lock. */ wpi_nic_unlock(sc); if (wpi_nic_lock(sc) == 0) { /* Stop TX scheduler. */ wpi_prph_write(sc, WPI_ALM_SCHED_MODE, 0); /* Stop all DMA channels. */ for (chnl = 0; chnl < WPI_NDMACHNLS; chnl++) { WPI_WRITE(sc, WPI_FH_TX_CONFIG(chnl), 0); for (ntries = 0; ntries < 100; ntries++) { tmp = WPI_READ(sc, WPI_FH_TX_STATUS); if ((tmp & WPI_FH_TX_STATUS_IDLE(chnl)) == WPI_FH_TX_STATUS_IDLE(chnl)) break; DELAY(10); } } wpi_nic_unlock(sc); } /* Stop RX ring. */ wpi_reset_rx_ring(sc, &sc->rxq); /* Reset all TX rings. */ for (qid = 0; qid < WPI_NTXQUEUES; qid++) wpi_reset_tx_ring(sc, &sc->txq[qid]); if (wpi_nic_lock(sc) == 0) { wpi_prph_write(sc, WPI_APMG_CLK_DIS, WPI_APMG_CLK_DMA_CLK_RQT); wpi_nic_unlock(sc); } DELAY(5); /* Power OFF adapter. */ wpi_apm_stop(sc); } int wpi_init(struct ifnet *ifp) { struct wpi_softc *sc = ifp->if_softc; struct ieee80211com *ic = &sc->sc_ic; int error; #ifdef notyet /* Check that the radio is not disabled by hardware switch. */ if (!(WPI_READ(sc, WPI_GP_CNTRL) & WPI_GP_CNTRL_RFKILL)) { printf("%s: radio is disabled by hardware switch\n", sc->sc_dev.dv_xname); error = EPERM; /* :-) */ goto fail; } #endif /* Read firmware images from the filesystem. */ if ((error = wpi_read_firmware(sc)) != 0) { printf("%s: could not read firmware\n", sc->sc_dev.dv_xname); goto fail; } /* Initialize hardware and upload firmware. */ error = wpi_hw_init(sc); free(sc->fw.data, M_DEVBUF); if (error != 0) { printf("%s: could not initialize hardware\n", sc->sc_dev.dv_xname); goto fail; } /* Configure adapter now that it is ready. */ if ((error = wpi_config(sc)) != 0) { printf("%s: could not configure device\n", sc->sc_dev.dv_xname); goto fail; } ifp->if_flags &= ~IFF_OACTIVE; ifp->if_flags |= IFF_RUNNING; if (ic->ic_opmode != IEEE80211_M_MONITOR) ieee80211_begin_scan(ifp); else ieee80211_new_state(ic, IEEE80211_S_RUN, -1); return 0; fail: wpi_stop(ifp, 1); return error; } void wpi_stop(struct ifnet *ifp, int disable) { struct wpi_softc *sc = ifp->if_softc; struct ieee80211com *ic = &sc->sc_ic; ifp->if_timer = sc->sc_tx_timer = 0; ifp->if_flags &= ~(IFF_RUNNING | IFF_OACTIVE); /* In case we were scanning, release the scan "lock". */ ic->ic_scan_lock = IEEE80211_SCAN_UNLOCKED; ieee80211_new_state(ic, IEEE80211_S_INIT, -1); /* Power OFF hardware. */ wpi_hw_stop(sc); /* Temperature sensor is no longer valid. */ sc->sensor.value = 0; sc->sensor.flags |= SENSOR_FINVALID; }