/* * Copyright (c) 2010 Broadcom Corporation * * Permission to use, copy, modify, and/or 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. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "wlc_types.h" #include "d11.h" #include "wlc_cfg.h" #include "wlc_rate.h" #include "wlc_scb.h" #include "wlc_pub.h" #include "wlc_key.h" #include "wlc_phy_shim.h" #include "phy/wlc_phy_hal.h" #include "wlc_channel.h" #include "wlc_main.h" #include "wl_export.h" #include "wl_ucode.h" #include "wlc_antsel.h" #include "pcie_core.h" #include "wlc_alloc.h" #include "wl_dbg.h" #include "wlc_bmac.h" #define TIMER_INTERVAL_WATCHDOG_BMAC 1000 /* watchdog timer, in unit of ms */ #define SYNTHPU_DLY_APHY_US 3700 /* a phy synthpu_dly time in us */ #define SYNTHPU_DLY_BPHY_US 1050 /* b/g phy synthpu_dly time in us, default */ #define SYNTHPU_DLY_NPHY_US 2048 /* n phy REV3 synthpu_dly time in us, default */ #define SYNTHPU_DLY_LPPHY_US 300 /* lpphy synthpu_dly time in us */ #define SYNTHPU_DLY_PHY_US_QT 100 /* QT synthpu_dly time in us */ #ifndef BMAC_DUP_TO_REMOVE #define WLC_RM_WAIT_TX_SUSPEND 4 /* Wait Tx Suspend */ #define ANTCNT 10 /* vanilla M_MAX_ANTCNT value */ #endif /* BMAC_DUP_TO_REMOVE */ #define DMAREG(wlc_hw, direction, fifonum) \ ((direction == DMA_TX) ? \ (void *)&(wlc_hw->regs->fifo64regs[fifonum].dmaxmt) : \ (void *)&(wlc_hw->regs->fifo64regs[fifonum].dmarcv)) /* * The following table lists the buffer memory allocated to xmt fifos in HW. * the size is in units of 256bytes(one block), total size is HW dependent * ucode has default fifo partition, sw can overwrite if necessary * * This is documented in twiki under the topic UcodeTxFifo. Please ensure * the twiki is updated before making changes. */ #define XMTFIFOTBL_STARTREV 20 /* Starting corerev for the fifo size table */ static u16 xmtfifo_sz[][NFIFO] = { {20, 192, 192, 21, 17, 5}, /* corerev 20: 5120, 49152, 49152, 5376, 4352, 1280 */ {9, 58, 22, 14, 14, 5}, /* corerev 21: 2304, 14848, 5632, 3584, 3584, 1280 */ {20, 192, 192, 21, 17, 5}, /* corerev 22: 5120, 49152, 49152, 5376, 4352, 1280 */ {20, 192, 192, 21, 17, 5}, /* corerev 23: 5120, 49152, 49152, 5376, 4352, 1280 */ {9, 58, 22, 14, 14, 5}, /* corerev 24: 2304, 14848, 5632, 3584, 3584, 1280 */ }; static void wlc_clkctl_clk(struct wlc_hw_info *wlc, uint mode); static void wlc_coreinit(struct wlc_info *wlc); /* used by wlc_wakeucode_init() */ static void wlc_write_inits(struct wlc_hw_info *wlc_hw, const struct d11init *inits); static void wlc_ucode_write(struct wlc_hw_info *wlc_hw, const u32 ucode[], const uint nbytes); static void wlc_ucode_download(struct wlc_hw_info *wlc); static void wlc_ucode_txant_set(struct wlc_hw_info *wlc_hw); /* used by wlc_dpc() */ static bool wlc_bmac_dotxstatus(struct wlc_hw_info *wlc, tx_status_t *txs, u32 s2); static bool wlc_bmac_txstatus(struct wlc_hw_info *wlc, bool bound, bool *fatal); static bool wlc_bmac_recv(struct wlc_hw_info *wlc_hw, uint fifo, bool bound); /* used by wlc_down() */ static void wlc_flushqueues(struct wlc_info *wlc); static void wlc_write_mhf(struct wlc_hw_info *wlc_hw, u16 *mhfs); static void wlc_mctrl_reset(struct wlc_hw_info *wlc_hw); static void wlc_corerev_fifofixup(struct wlc_hw_info *wlc_hw); static bool wlc_bmac_tx_fifo_suspended(struct wlc_hw_info *wlc_hw, uint tx_fifo); static void wlc_bmac_tx_fifo_suspend(struct wlc_hw_info *wlc_hw, uint tx_fifo); static void wlc_bmac_tx_fifo_resume(struct wlc_hw_info *wlc_hw, uint tx_fifo); /* Low Level Prototypes */ static int wlc_bmac_bandtype(struct wlc_hw_info *wlc_hw); static void wlc_bmac_info_init(struct wlc_hw_info *wlc_hw); static void wlc_bmac_xtal(struct wlc_hw_info *wlc_hw, bool want); static u16 wlc_bmac_read_objmem(struct wlc_hw_info *wlc_hw, uint offset, u32 sel); static void wlc_bmac_write_objmem(struct wlc_hw_info *wlc_hw, uint offset, u16 v, u32 sel); static void wlc_bmac_core_phy_clk(struct wlc_hw_info *wlc_hw, bool clk); static bool wlc_bmac_attach_dmapio(struct wlc_info *wlc, uint j, bool wme); static void wlc_bmac_detach_dmapio(struct wlc_hw_info *wlc_hw); static void wlc_ucode_bsinit(struct wlc_hw_info *wlc_hw); static bool wlc_validboardtype(struct wlc_hw_info *wlc); static bool wlc_isgoodchip(struct wlc_hw_info *wlc_hw); static bool wlc_bmac_validate_chip_access(struct wlc_hw_info *wlc_hw); static char *wlc_get_macaddr(struct wlc_hw_info *wlc_hw); static void wlc_mhfdef(struct wlc_info *wlc, u16 *mhfs, u16 mhf2_init); static void wlc_mctrl_write(struct wlc_hw_info *wlc_hw); static void wlc_bmac_mute(struct wlc_hw_info *wlc_hw, bool want, mbool flags); static void wlc_ucode_mute_override_set(struct wlc_hw_info *wlc_hw); static void wlc_ucode_mute_override_clear(struct wlc_hw_info *wlc_hw); static u32 wlc_wlintrsoff(struct wlc_info *wlc); static void wlc_wlintrsrestore(struct wlc_info *wlc, u32 macintmask); static void wlc_gpio_init(struct wlc_info *wlc); static void wlc_write_hw_bcntemplate0(struct wlc_hw_info *wlc_hw, void *bcn, int len); static void wlc_write_hw_bcntemplate1(struct wlc_hw_info *wlc_hw, void *bcn, int len); static void wlc_bmac_bsinit(struct wlc_info *wlc, chanspec_t chanspec); static u32 wlc_setband_inact(struct wlc_info *wlc, uint bandunit); static void wlc_bmac_setband(struct wlc_hw_info *wlc_hw, uint bandunit, chanspec_t chanspec); static void wlc_bmac_update_slot_timing(struct wlc_hw_info *wlc_hw, bool shortslot); static void wlc_upd_ofdm_pctl1_table(struct wlc_hw_info *wlc_hw); static u16 wlc_bmac_ofdm_ratetable_offset(struct wlc_hw_info *wlc_hw, u8 rate); /* === Low Level functions === */ void wlc_bmac_set_shortslot(struct wlc_hw_info *wlc_hw, bool shortslot) { wlc_hw->shortslot = shortslot; if (BAND_2G(wlc_bmac_bandtype(wlc_hw)) && wlc_hw->up) { wlc_suspend_mac_and_wait(wlc_hw->wlc); wlc_bmac_update_slot_timing(wlc_hw, shortslot); wlc_enable_mac(wlc_hw->wlc); } } /* * Update the slot timing for standard 11b/g (20us slots) * or shortslot 11g (9us slots) * The PSM needs to be suspended for this call. */ static void wlc_bmac_update_slot_timing(struct wlc_hw_info *wlc_hw, bool shortslot) { d11regs_t *regs; regs = wlc_hw->regs; if (shortslot) { /* 11g short slot: 11a timing */ W_REG(®s->ifs_slot, 0x0207); /* APHY_SLOT_TIME */ wlc_bmac_write_shm(wlc_hw, M_DOT11_SLOT, APHY_SLOT_TIME); } else { /* 11g long slot: 11b timing */ W_REG(®s->ifs_slot, 0x0212); /* BPHY_SLOT_TIME */ wlc_bmac_write_shm(wlc_hw, M_DOT11_SLOT, BPHY_SLOT_TIME); } } static void WLBANDINITFN(wlc_ucode_bsinit) (struct wlc_hw_info *wlc_hw) { /* init microcode host flags */ wlc_write_mhf(wlc_hw, wlc_hw->band->mhfs); /* do band-specific ucode IHR, SHM, and SCR inits */ if (D11REV_IS(wlc_hw->corerev, 23)) { if (WLCISNPHY(wlc_hw->band)) { wlc_write_inits(wlc_hw, d11n0bsinitvals16); } else { WL_ERROR("%s: wl%d: unsupported phy in corerev %d\n", __func__, wlc_hw->unit, wlc_hw->corerev); } } else { if (D11REV_IS(wlc_hw->corerev, 24)) { if (WLCISLCNPHY(wlc_hw->band)) { wlc_write_inits(wlc_hw, d11lcn0bsinitvals24); } else WL_ERROR("%s: wl%d: unsupported phy in corerev %d\n", __func__, wlc_hw->unit, wlc_hw->corerev); } else { WL_ERROR("%s: wl%d: unsupported corerev %d\n", __func__, wlc_hw->unit, wlc_hw->corerev); } } } /* switch to new band but leave it inactive */ static u32 WLBANDINITFN(wlc_setband_inact) (struct wlc_info *wlc, uint bandunit) { struct wlc_hw_info *wlc_hw = wlc->hw; u32 macintmask; WL_TRACE("wl%d: wlc_setband_inact\n", wlc_hw->unit); ASSERT(bandunit != wlc_hw->band->bandunit); ASSERT(si_iscoreup(wlc_hw->sih)); ASSERT((R_REG(&wlc_hw->regs->maccontrol) & MCTL_EN_MAC) == 0); /* disable interrupts */ macintmask = wl_intrsoff(wlc->wl); /* radio off */ wlc_phy_switch_radio(wlc_hw->band->pi, OFF); ASSERT(wlc_hw->clk); wlc_bmac_core_phy_clk(wlc_hw, OFF); wlc_setxband(wlc_hw, bandunit); return macintmask; } /* Process received frames */ /* * Return true if more frames need to be processed. false otherwise. * Param 'bound' indicates max. # frames to process before break out. */ static bool BCMFASTPATH wlc_bmac_recv(struct wlc_hw_info *wlc_hw, uint fifo, bool bound) { struct sk_buff *p; struct sk_buff *head = NULL; struct sk_buff *tail = NULL; uint n = 0; uint bound_limit = bound ? wlc_hw->wlc->pub->tunables->rxbnd : -1; u32 tsf_h, tsf_l; wlc_d11rxhdr_t *wlc_rxhdr = NULL; WL_TRACE("wl%d: %s\n", wlc_hw->unit, __func__); /* gather received frames */ while ((p = dma_rx(wlc_hw->di[fifo]))) { if (!tail) head = tail = p; else { tail->prev = p; tail = p; } /* !give others some time to run! */ if (++n >= bound_limit) break; } /* get the TSF REG reading */ wlc_bmac_read_tsf(wlc_hw, &tsf_l, &tsf_h); /* post more rbufs */ dma_rxfill(wlc_hw->di[fifo]); /* process each frame */ while ((p = head) != NULL) { head = head->prev; p->prev = NULL; /* record the tsf_l in wlc_rxd11hdr */ wlc_rxhdr = (wlc_d11rxhdr_t *) p->data; wlc_rxhdr->tsf_l = cpu_to_le32(tsf_l); /* compute the RSSI from d11rxhdr and record it in wlc_rxd11hr */ wlc_phy_rssi_compute(wlc_hw->band->pi, wlc_rxhdr); wlc_recv(wlc_hw->wlc, p); } return n >= bound_limit; } /* second-level interrupt processing * Return true if another dpc needs to be re-scheduled. false otherwise. * Param 'bounded' indicates if applicable loops should be bounded. */ bool BCMFASTPATH wlc_dpc(struct wlc_info *wlc, bool bounded) { u32 macintstatus; struct wlc_hw_info *wlc_hw = wlc->hw; d11regs_t *regs = wlc_hw->regs; bool fatal = false; if (DEVICEREMOVED(wlc)) { WL_ERROR("wl%d: %s: dead chip\n", wlc_hw->unit, __func__); wl_down(wlc->wl); return false; } /* grab and clear the saved software intstatus bits */ macintstatus = wlc->macintstatus; wlc->macintstatus = 0; WL_TRACE("wl%d: wlc_dpc: macintstatus 0x%x\n", wlc_hw->unit, macintstatus); if (macintstatus & MI_PRQ) { /* Process probe request FIFO */ ASSERT(0 && "PRQ Interrupt in non-MBSS"); } /* BCN template is available */ /* ZZZ: Use AP_ACTIVE ? */ if (AP_ENAB(wlc->pub) && (!APSTA_ENAB(wlc->pub) || wlc->aps_associated) && (macintstatus & MI_BCNTPL)) { wlc_update_beacon(wlc); } /* PMQ entry addition */ if (macintstatus & MI_PMQ) { } /* tx status */ if (macintstatus & MI_TFS) { if (wlc_bmac_txstatus(wlc->hw, bounded, &fatal)) wlc->macintstatus |= MI_TFS; if (fatal) { WL_ERROR("MI_TFS: fatal\n"); goto fatal; } } if (macintstatus & (MI_TBTT | MI_DTIM_TBTT)) wlc_tbtt(wlc, regs); /* ATIM window end */ if (macintstatus & MI_ATIMWINEND) { WL_TRACE("wlc_isr: end of ATIM window\n"); OR_REG(®s->maccommand, wlc->qvalid); wlc->qvalid = 0; } /* phy tx error */ if (macintstatus & MI_PHYTXERR) { wlc->pub->_cnt->txphyerr++; } /* received data or control frame, MI_DMAINT is indication of RX_FIFO interrupt */ if (macintstatus & MI_DMAINT) { if (wlc_bmac_recv(wlc_hw, RX_FIFO, bounded)) { wlc->macintstatus |= MI_DMAINT; } } /* TX FIFO suspend/flush completion */ if (macintstatus & MI_TXSTOP) { if (wlc_bmac_tx_fifo_suspended(wlc_hw, TX_DATA_FIFO)) { /* WL_ERROR("dpc: fifo_suspend_comlete\n"); */ } } /* noise sample collected */ if (macintstatus & MI_BG_NOISE) { wlc_phy_noise_sample_intr(wlc_hw->band->pi); } if (macintstatus & MI_GP0) { WL_ERROR("wl%d: PSM microcode watchdog fired at %d (seconds). Resetting.\n", wlc_hw->unit, wlc_hw->now); printk_once("%s : PSM Watchdog, chipid 0x%x, chiprev 0x%x\n", __func__, wlc_hw->sih->chip, wlc_hw->sih->chiprev); wlc->pub->_cnt->psmwds++; /* big hammer */ wl_init(wlc->wl); } /* gptimer timeout */ if (macintstatus & MI_TO) { W_REG(®s->gptimer, 0); } if (macintstatus & MI_RFDISABLE) { WL_TRACE("wl%d: BMAC Detected a change on the RF Disable Input\n", wlc_hw->unit); wlc->pub->_cnt->rfdisable++; wl_rfkill_set_hw_state(wlc->wl); } /* send any enq'd tx packets. Just makes sure to jump start tx */ if (!pktq_empty(&wlc->active_queue->q)) wlc_send_q(wlc, wlc->active_queue); ASSERT(wlc_ps_check(wlc)); /* make sure the bound indication and the implementation are in sync */ ASSERT(bounded == true || wlc->macintstatus == 0); /* it isn't done and needs to be resched if macintstatus is non-zero */ return wlc->macintstatus != 0; fatal: wl_init(wlc->wl); return wlc->macintstatus != 0; } /* common low-level watchdog code */ void wlc_bmac_watchdog(void *arg) { struct wlc_info *wlc = (struct wlc_info *) arg; struct wlc_hw_info *wlc_hw = wlc->hw; WL_TRACE("wl%d: wlc_bmac_watchdog\n", wlc_hw->unit); if (!wlc_hw->up) return; /* increment second count */ wlc_hw->now++; /* Check for FIFO error interrupts */ wlc_bmac_fifoerrors(wlc_hw); /* make sure RX dma has buffers */ dma_rxfill(wlc->hw->di[RX_FIFO]); wlc_phy_watchdog(wlc_hw->band->pi); } void wlc_bmac_set_chanspec(struct wlc_hw_info *wlc_hw, chanspec_t chanspec, bool mute, struct txpwr_limits *txpwr) { uint bandunit; WL_TRACE("wl%d: wlc_bmac_set_chanspec 0x%x\n", wlc_hw->unit, chanspec); wlc_hw->chanspec = chanspec; /* Switch bands if necessary */ if (NBANDS_HW(wlc_hw) > 1) { bandunit = CHSPEC_WLCBANDUNIT(chanspec); if (wlc_hw->band->bandunit != bandunit) { /* wlc_bmac_setband disables other bandunit, * use light band switch if not up yet */ if (wlc_hw->up) { wlc_phy_chanspec_radio_set(wlc_hw-> bandstate[bandunit]-> pi, chanspec); wlc_bmac_setband(wlc_hw, bandunit, chanspec); } else { wlc_setxband(wlc_hw, bandunit); } } } wlc_phy_initcal_enable(wlc_hw->band->pi, !mute); if (!wlc_hw->up) { if (wlc_hw->clk) wlc_phy_txpower_limit_set(wlc_hw->band->pi, txpwr, chanspec); wlc_phy_chanspec_radio_set(wlc_hw->band->pi, chanspec); } else { wlc_phy_chanspec_set(wlc_hw->band->pi, chanspec); wlc_phy_txpower_limit_set(wlc_hw->band->pi, txpwr, chanspec); /* Update muting of the channel */ wlc_bmac_mute(wlc_hw, mute, 0); } } int wlc_bmac_state_get(struct wlc_hw_info *wlc_hw, wlc_bmac_state_t *state) { state->machwcap = wlc_hw->machwcap; return 0; } static bool wlc_bmac_attach_dmapio(struct wlc_info *wlc, uint j, bool wme) { uint i; char name[8]; /* ucode host flag 2 needed for pio mode, independent of band and fifo */ u16 pio_mhf2 = 0; struct wlc_hw_info *wlc_hw = wlc->hw; uint unit = wlc_hw->unit; wlc_tunables_t *tune = wlc->pub->tunables; /* name and offsets for dma_attach */ snprintf(name, sizeof(name), "wl%d", unit); if (wlc_hw->di[0] == 0) { /* Init FIFOs */ uint addrwidth; int dma_attach_err = 0; /* Find out the DMA addressing capability and let OS know * All the channels within one DMA core have 'common-minimum' same * capability */ addrwidth = dma_addrwidth(wlc_hw->sih, DMAREG(wlc_hw, DMA_TX, 0)); if (!wl_alloc_dma_resources(wlc_hw->wlc->wl, addrwidth)) { WL_ERROR("wl%d: wlc_attach: alloc_dma_resources failed\n", unit); return false; } /* * FIFO 0 * TX: TX_AC_BK_FIFO (TX AC Background data packets) * RX: RX_FIFO (RX data packets) */ ASSERT(TX_AC_BK_FIFO == 0); ASSERT(RX_FIFO == 0); wlc_hw->di[0] = dma_attach(name, wlc_hw->sih, (wme ? DMAREG(wlc_hw, DMA_TX, 0) : NULL), DMAREG(wlc_hw, DMA_RX, 0), (wme ? tune->ntxd : 0), tune->nrxd, tune->rxbufsz, -1, tune->nrxbufpost, WL_HWRXOFF, &wl_msg_level); dma_attach_err |= (NULL == wlc_hw->di[0]); /* * FIFO 1 * TX: TX_AC_BE_FIFO (TX AC Best-Effort data packets) * (legacy) TX_DATA_FIFO (TX data packets) * RX: UNUSED */ ASSERT(TX_AC_BE_FIFO == 1); ASSERT(TX_DATA_FIFO == 1); wlc_hw->di[1] = dma_attach(name, wlc_hw->sih, DMAREG(wlc_hw, DMA_TX, 1), NULL, tune->ntxd, 0, 0, -1, 0, 0, &wl_msg_level); dma_attach_err |= (NULL == wlc_hw->di[1]); /* * FIFO 2 * TX: TX_AC_VI_FIFO (TX AC Video data packets) * RX: UNUSED */ ASSERT(TX_AC_VI_FIFO == 2); wlc_hw->di[2] = dma_attach(name, wlc_hw->sih, DMAREG(wlc_hw, DMA_TX, 2), NULL, tune->ntxd, 0, 0, -1, 0, 0, &wl_msg_level); dma_attach_err |= (NULL == wlc_hw->di[2]); /* * FIFO 3 * TX: TX_AC_VO_FIFO (TX AC Voice data packets) * (legacy) TX_CTL_FIFO (TX control & mgmt packets) */ ASSERT(TX_AC_VO_FIFO == 3); ASSERT(TX_CTL_FIFO == 3); wlc_hw->di[3] = dma_attach(name, wlc_hw->sih, DMAREG(wlc_hw, DMA_TX, 3), NULL, tune->ntxd, 0, 0, -1, 0, 0, &wl_msg_level); dma_attach_err |= (NULL == wlc_hw->di[3]); /* Cleaner to leave this as if with AP defined */ if (dma_attach_err) { WL_ERROR("wl%d: wlc_attach: dma_attach failed\n", unit); return false; } /* get pointer to dma engine tx flow control variable */ for (i = 0; i < NFIFO; i++) if (wlc_hw->di[i]) wlc_hw->txavail[i] = (uint *) dma_getvar(wlc_hw->di[i], "&txavail"); } /* initial ucode host flags */ wlc_mhfdef(wlc, wlc_hw->band->mhfs, pio_mhf2); return true; } static void wlc_bmac_detach_dmapio(struct wlc_hw_info *wlc_hw) { uint j; for (j = 0; j < NFIFO; j++) { if (wlc_hw->di[j]) { dma_detach(wlc_hw->di[j]); wlc_hw->di[j] = NULL; } } } /* low level attach * run backplane attach, init nvram * run phy attach * initialize software state for each core and band * put the whole chip in reset(driver down state), no clock */ int wlc_bmac_attach(struct wlc_info *wlc, u16 vendor, u16 device, uint unit, bool piomode, void *regsva, uint bustype, void *btparam) { struct wlc_hw_info *wlc_hw; d11regs_t *regs; char *macaddr = NULL; char *vars; uint err = 0; uint j; bool wme = false; shared_phy_params_t sha_params; WL_TRACE("wl%d: wlc_bmac_attach: vendor 0x%x device 0x%x\n", unit, vendor, device); ASSERT(sizeof(wlc_d11rxhdr_t) <= WL_HWRXOFF); wme = true; wlc_hw = wlc->hw; wlc_hw->wlc = wlc; wlc_hw->unit = unit; wlc_hw->band = wlc_hw->bandstate[0]; wlc_hw->_piomode = piomode; /* populate struct wlc_hw_info with default values */ wlc_bmac_info_init(wlc_hw); /* * Do the hardware portion of the attach. * Also initialize software state that depends on the particular hardware * we are running. */ wlc_hw->sih = si_attach((uint) device, regsva, bustype, btparam, &wlc_hw->vars, &wlc_hw->vars_size); if (wlc_hw->sih == NULL) { WL_ERROR("wl%d: wlc_bmac_attach: si_attach failed\n", unit); err = 11; goto fail; } vars = wlc_hw->vars; /* * Get vendid/devid nvram overwrites, which could be different * than those the BIOS recognizes for devices on PCMCIA_BUS, * SDIO_BUS, and SROMless devices on PCI_BUS. */ #ifdef BCMBUSTYPE bustype = BCMBUSTYPE; #endif if (bustype != SI_BUS) { char *var; var = getvar(vars, "vendid"); if (var) { vendor = (u16) simple_strtoul(var, NULL, 0); WL_ERROR("Overriding vendor id = 0x%x\n", vendor); } var = getvar(vars, "devid"); if (var) { u16 devid = (u16) simple_strtoul(var, NULL, 0); if (devid != 0xffff) { device = devid; WL_ERROR("Overriding device id = 0x%x\n", device); } } /* verify again the device is supported */ if (!wlc_chipmatch(vendor, device)) { WL_ERROR("wl%d: wlc_bmac_attach: Unsupported vendor/device (0x%x/0x%x)\n", unit, vendor, device); err = 12; goto fail; } } wlc_hw->vendorid = vendor; wlc_hw->deviceid = device; /* set bar0 window to point at D11 core */ wlc_hw->regs = (d11regs_t *) si_setcore(wlc_hw->sih, D11_CORE_ID, 0); wlc_hw->corerev = si_corerev(wlc_hw->sih); regs = wlc_hw->regs; wlc->regs = wlc_hw->regs; /* validate chip, chiprev and corerev */ if (!wlc_isgoodchip(wlc_hw)) { err = 13; goto fail; } /* initialize power control registers */ si_clkctl_init(wlc_hw->sih); /* request fastclock and force fastclock for the rest of attach * bring the d11 core out of reset. * For PMU chips, the first wlc_clkctl_clk is no-op since core-clk is still false; * But it will be called again inside wlc_corereset, after d11 is out of reset. */ wlc_clkctl_clk(wlc_hw, CLK_FAST); wlc_bmac_corereset(wlc_hw, WLC_USE_COREFLAGS); if (!wlc_bmac_validate_chip_access(wlc_hw)) { WL_ERROR("wl%d: wlc_bmac_attach: validate_chip_access failed\n", unit); err = 14; goto fail; } /* get the board rev, used just below */ j = getintvar(vars, "boardrev"); /* promote srom boardrev of 0xFF to 1 */ if (j == BOARDREV_PROMOTABLE) j = BOARDREV_PROMOTED; wlc_hw->boardrev = (u16) j; if (!wlc_validboardtype(wlc_hw)) { WL_ERROR("wl%d: wlc_bmac_attach: Unsupported Broadcom board type (0x%x)" " or revision level (0x%x)\n", unit, wlc_hw->sih->boardtype, wlc_hw->boardrev); err = 15; goto fail; } wlc_hw->sromrev = (u8) getintvar(vars, "sromrev"); wlc_hw->boardflags = (u32) getintvar(vars, "boardflags"); wlc_hw->boardflags2 = (u32) getintvar(vars, "boardflags2"); if (wlc_hw->boardflags & BFL_NOPLLDOWN) wlc_bmac_pllreq(wlc_hw, true, WLC_PLLREQ_SHARED); if ((wlc_hw->sih->bustype == PCI_BUS) && (si_pci_war16165(wlc_hw->sih))) wlc->war16165 = true; /* check device id(srom, nvram etc.) to set bands */ if (wlc_hw->deviceid == BCM43224_D11N_ID) { /* Dualband boards */ wlc_hw->_nbands = 2; } else wlc_hw->_nbands = 1; if ((wlc_hw->sih->chip == BCM43225_CHIP_ID)) wlc_hw->_nbands = 1; /* BMAC_NOTE: remove init of pub values when wlc_attach() unconditionally does the * init of these values */ wlc->vendorid = wlc_hw->vendorid; wlc->deviceid = wlc_hw->deviceid; wlc->pub->sih = wlc_hw->sih; wlc->pub->corerev = wlc_hw->corerev; wlc->pub->sromrev = wlc_hw->sromrev; wlc->pub->boardrev = wlc_hw->boardrev; wlc->pub->boardflags = wlc_hw->boardflags; wlc->pub->boardflags2 = wlc_hw->boardflags2; wlc->pub->_nbands = wlc_hw->_nbands; wlc_hw->physhim = wlc_phy_shim_attach(wlc_hw, wlc->wl, wlc); if (wlc_hw->physhim == NULL) { WL_ERROR("wl%d: wlc_bmac_attach: wlc_phy_shim_attach failed\n", unit); err = 25; goto fail; } /* pass all the parameters to wlc_phy_shared_attach in one struct */ sha_params.sih = wlc_hw->sih; sha_params.physhim = wlc_hw->physhim; sha_params.unit = unit; sha_params.corerev = wlc_hw->corerev; sha_params.vars = vars; sha_params.vid = wlc_hw->vendorid; sha_params.did = wlc_hw->deviceid; sha_params.chip = wlc_hw->sih->chip; sha_params.chiprev = wlc_hw->sih->chiprev; sha_params.chippkg = wlc_hw->sih->chippkg; sha_params.sromrev = wlc_hw->sromrev; sha_params.boardtype = wlc_hw->sih->boardtype; sha_params.boardrev = wlc_hw->boardrev; sha_params.boardvendor = wlc_hw->sih->boardvendor; sha_params.boardflags = wlc_hw->boardflags; sha_params.boardflags2 = wlc_hw->boardflags2; sha_params.bustype = wlc_hw->sih->bustype; sha_params.buscorerev = wlc_hw->sih->buscorerev; /* alloc and save pointer to shared phy state area */ wlc_hw->phy_sh = wlc_phy_shared_attach(&sha_params); if (!wlc_hw->phy_sh) { err = 16; goto fail; } /* initialize software state for each core and band */ for (j = 0; j < NBANDS_HW(wlc_hw); j++) { /* * band0 is always 2.4Ghz * band1, if present, is 5Ghz */ /* So if this is a single band 11a card, use band 1 */ if (IS_SINGLEBAND_5G(wlc_hw->deviceid)) j = BAND_5G_INDEX; wlc_setxband(wlc_hw, j); wlc_hw->band->bandunit = j; wlc_hw->band->bandtype = j ? WLC_BAND_5G : WLC_BAND_2G; wlc->band->bandunit = j; wlc->band->bandtype = j ? WLC_BAND_5G : WLC_BAND_2G; wlc->core->coreidx = si_coreidx(wlc_hw->sih); wlc_hw->machwcap = R_REG(®s->machwcap); wlc_hw->machwcap_backup = wlc_hw->machwcap; /* init tx fifo size */ ASSERT((wlc_hw->corerev - XMTFIFOTBL_STARTREV) < ARRAY_SIZE(xmtfifo_sz)); wlc_hw->xmtfifo_sz = xmtfifo_sz[(wlc_hw->corerev - XMTFIFOTBL_STARTREV)]; /* Get a phy for this band */ wlc_hw->band->pi = wlc_phy_attach(wlc_hw->phy_sh, (void *)regs, wlc_bmac_bandtype(wlc_hw), vars); if (wlc_hw->band->pi == NULL) { WL_ERROR("wl%d: wlc_bmac_attach: wlc_phy_attach failed\n", unit); err = 17; goto fail; } wlc_phy_machwcap_set(wlc_hw->band->pi, wlc_hw->machwcap); wlc_phy_get_phyversion(wlc_hw->band->pi, &wlc_hw->band->phytype, &wlc_hw->band->phyrev, &wlc_hw->band->radioid, &wlc_hw->band->radiorev); wlc_hw->band->abgphy_encore = wlc_phy_get_encore(wlc_hw->band->pi); wlc->band->abgphy_encore = wlc_phy_get_encore(wlc_hw->band->pi); wlc_hw->band->core_flags = wlc_phy_get_coreflags(wlc_hw->band->pi); /* verify good phy_type & supported phy revision */ if (WLCISNPHY(wlc_hw->band)) { if (NCONF_HAS(wlc_hw->band->phyrev)) goto good_phy; else goto bad_phy; } else if (WLCISLCNPHY(wlc_hw->band)) { if (LCNCONF_HAS(wlc_hw->band->phyrev)) goto good_phy; else goto bad_phy; } else { bad_phy: WL_ERROR("wl%d: wlc_bmac_attach: unsupported phy type/rev (%d/%d)\n", unit, wlc_hw->band->phytype, wlc_hw->band->phyrev); err = 18; goto fail; } good_phy: /* BMAC_NOTE: wlc->band->pi should not be set below and should be done in the * high level attach. However we can not make that change until all low level access * is changed to wlc_hw->band->pi. Instead do the wlc->band->pi init below, keeping * wlc_hw->band->pi as well for incremental update of low level fns, and cut over * low only init when all fns updated. */ wlc->band->pi = wlc_hw->band->pi; wlc->band->phytype = wlc_hw->band->phytype; wlc->band->phyrev = wlc_hw->band->phyrev; wlc->band->radioid = wlc_hw->band->radioid; wlc->band->radiorev = wlc_hw->band->radiorev; /* default contention windows size limits */ wlc_hw->band->CWmin = APHY_CWMIN; wlc_hw->band->CWmax = PHY_CWMAX; if (!wlc_bmac_attach_dmapio(wlc, j, wme)) { err = 19; goto fail; } } /* disable core to match driver "down" state */ wlc_coredisable(wlc_hw); /* Match driver "down" state */ if (wlc_hw->sih->bustype == PCI_BUS) si_pci_down(wlc_hw->sih); /* register sb interrupt callback functions */ si_register_intr_callback(wlc_hw->sih, (void *)wlc_wlintrsoff, (void *)wlc_wlintrsrestore, NULL, wlc); /* turn off pll and xtal to match driver "down" state */ wlc_bmac_xtal(wlc_hw, OFF); /* ********************************************************************* * The hardware is in the DOWN state at this point. D11 core * or cores are in reset with clocks off, and the board PLLs * are off if possible. * * Beyond this point, wlc->sbclk == false and chip registers * should not be touched. ********************************************************************* */ /* init etheraddr state variables */ macaddr = wlc_get_macaddr(wlc_hw); if (macaddr == NULL) { WL_ERROR("wl%d: wlc_bmac_attach: macaddr not found\n", unit); err = 21; goto fail; } bcm_ether_atoe(macaddr, wlc_hw->etheraddr); if (is_broadcast_ether_addr(wlc_hw->etheraddr) || is_zero_ether_addr(wlc_hw->etheraddr)) { WL_ERROR("wl%d: wlc_bmac_attach: bad macaddr %s\n", unit, macaddr); err = 22; goto fail; } WL_TRACE("%s:: deviceid 0x%x nbands %d board 0x%x macaddr: %s\n", __func__, wlc_hw->deviceid, wlc_hw->_nbands, wlc_hw->sih->boardtype, macaddr); return err; fail: WL_ERROR("wl%d: wlc_bmac_attach: failed with err %d\n", unit, err); return err; } /* * Initialize wlc_info default values ... * may get overrides later in this function * BMAC_NOTES, move low out and resolve the dangling ones */ static void wlc_bmac_info_init(struct wlc_hw_info *wlc_hw) { struct wlc_info *wlc = wlc_hw->wlc; /* set default sw macintmask value */ wlc->defmacintmask = DEF_MACINTMASK; /* various 802.11g modes */ wlc_hw->shortslot = false; wlc_hw->SFBL = RETRY_SHORT_FB; wlc_hw->LFBL = RETRY_LONG_FB; /* default mac retry limits */ wlc_hw->SRL = RETRY_SHORT_DEF; wlc_hw->LRL = RETRY_LONG_DEF; wlc_hw->chanspec = CH20MHZ_CHSPEC(1); } /* * low level detach */ int wlc_bmac_detach(struct wlc_info *wlc) { uint i; struct wlc_hwband *band; struct wlc_hw_info *wlc_hw = wlc->hw; int callbacks; callbacks = 0; if (wlc_hw->sih) { /* detach interrupt sync mechanism since interrupt is disabled and per-port * interrupt object may has been freed. this must be done before sb core switch */ si_deregister_intr_callback(wlc_hw->sih); if (wlc_hw->sih->bustype == PCI_BUS) si_pci_sleep(wlc_hw->sih); } wlc_bmac_detach_dmapio(wlc_hw); band = wlc_hw->band; for (i = 0; i < NBANDS_HW(wlc_hw); i++) { if (band->pi) { /* Detach this band's phy */ wlc_phy_detach(band->pi); band->pi = NULL; } band = wlc_hw->bandstate[OTHERBANDUNIT(wlc)]; } /* Free shared phy state */ wlc_phy_shared_detach(wlc_hw->phy_sh); wlc_phy_shim_detach(wlc_hw->physhim); /* free vars */ kfree(wlc_hw->vars); wlc_hw->vars = NULL; if (wlc_hw->sih) { si_detach(wlc_hw->sih); wlc_hw->sih = NULL; } return callbacks; } void wlc_bmac_reset(struct wlc_hw_info *wlc_hw) { WL_TRACE("wl%d: wlc_bmac_reset\n", wlc_hw->unit); wlc_hw->wlc->pub->_cnt->reset++; /* reset the core */ if (!DEVICEREMOVED(wlc_hw->wlc)) wlc_bmac_corereset(wlc_hw, WLC_USE_COREFLAGS); /* purge the dma rings */ wlc_flushqueues(wlc_hw->wlc); wlc_reset_bmac_done(wlc_hw->wlc); } void wlc_bmac_init(struct wlc_hw_info *wlc_hw, chanspec_t chanspec, bool mute) { u32 macintmask; bool fastclk; struct wlc_info *wlc = wlc_hw->wlc; WL_TRACE("wl%d: wlc_bmac_init\n", wlc_hw->unit); /* request FAST clock if not on */ fastclk = wlc_hw->forcefastclk; if (!fastclk) wlc_clkctl_clk(wlc_hw, CLK_FAST); /* disable interrupts */ macintmask = wl_intrsoff(wlc->wl); /* set up the specified band and chanspec */ wlc_setxband(wlc_hw, CHSPEC_WLCBANDUNIT(chanspec)); wlc_phy_chanspec_radio_set(wlc_hw->band->pi, chanspec); /* do one-time phy inits and calibration */ wlc_phy_cal_init(wlc_hw->band->pi); /* core-specific initialization */ wlc_coreinit(wlc); /* suspend the tx fifos and mute the phy for preism cac time */ if (mute) wlc_bmac_mute(wlc_hw, ON, PHY_MUTE_FOR_PREISM); /* band-specific inits */ wlc_bmac_bsinit(wlc, chanspec); /* restore macintmask */ wl_intrsrestore(wlc->wl, macintmask); /* seed wake_override with WLC_WAKE_OVERRIDE_MACSUSPEND since the mac is suspended * and wlc_enable_mac() will clear this override bit. */ mboolset(wlc_hw->wake_override, WLC_WAKE_OVERRIDE_MACSUSPEND); /* * initialize mac_suspend_depth to 1 to match ucode initial suspended state */ wlc_hw->mac_suspend_depth = 1; /* restore the clk */ if (!fastclk) wlc_clkctl_clk(wlc_hw, CLK_DYNAMIC); } int wlc_bmac_up_prep(struct wlc_hw_info *wlc_hw) { uint coremask; WL_TRACE("wl%d: %s:\n", wlc_hw->unit, __func__); ASSERT(wlc_hw->wlc->pub->hw_up && wlc_hw->wlc->macintmask == 0); /* * Enable pll and xtal, initialize the power control registers, * and force fastclock for the remainder of wlc_up(). */ wlc_bmac_xtal(wlc_hw, ON); si_clkctl_init(wlc_hw->sih); wlc_clkctl_clk(wlc_hw, CLK_FAST); /* * Configure pci/pcmcia here instead of in wlc_attach() * to allow mfg hotswap: down, hotswap (chip power cycle), up. */ coremask = (1 << wlc_hw->wlc->core->coreidx); if (wlc_hw->sih->bustype == PCI_BUS) si_pci_setup(wlc_hw->sih, coremask); ASSERT(si_coreid(wlc_hw->sih) == D11_CORE_ID); /* * Need to read the hwradio status here to cover the case where the system * is loaded with the hw radio disabled. We do not want to bring the driver up in this case. */ if (wlc_bmac_radio_read_hwdisabled(wlc_hw)) { /* put SB PCI in down state again */ if (wlc_hw->sih->bustype == PCI_BUS) si_pci_down(wlc_hw->sih); wlc_bmac_xtal(wlc_hw, OFF); return BCME_RADIOOFF; } if (wlc_hw->sih->bustype == PCI_BUS) si_pci_up(wlc_hw->sih); /* reset the d11 core */ wlc_bmac_corereset(wlc_hw, WLC_USE_COREFLAGS); return 0; } int wlc_bmac_up_finish(struct wlc_hw_info *wlc_hw) { WL_TRACE("wl%d: %s:\n", wlc_hw->unit, __func__); wlc_hw->up = true; wlc_phy_hw_state_upd(wlc_hw->band->pi, true); /* FULLY enable dynamic power control and d11 core interrupt */ wlc_clkctl_clk(wlc_hw, CLK_DYNAMIC); ASSERT(wlc_hw->wlc->macintmask == 0); wl_intrson(wlc_hw->wlc->wl); return 0; } int wlc_bmac_down_prep(struct wlc_hw_info *wlc_hw) { bool dev_gone; uint callbacks = 0; WL_TRACE("wl%d: %s:\n", wlc_hw->unit, __func__); if (!wlc_hw->up) return callbacks; dev_gone = DEVICEREMOVED(wlc_hw->wlc); /* disable interrupts */ if (dev_gone) wlc_hw->wlc->macintmask = 0; else { /* now disable interrupts */ wl_intrsoff(wlc_hw->wlc->wl); /* ensure we're running on the pll clock again */ wlc_clkctl_clk(wlc_hw, CLK_FAST); } /* down phy at the last of this stage */ callbacks += wlc_phy_down(wlc_hw->band->pi); return callbacks; } int wlc_bmac_down_finish(struct wlc_hw_info *wlc_hw) { uint callbacks = 0; bool dev_gone; WL_TRACE("wl%d: %s:\n", wlc_hw->unit, __func__); if (!wlc_hw->up) return callbacks; wlc_hw->up = false; wlc_phy_hw_state_upd(wlc_hw->band->pi, false); dev_gone = DEVICEREMOVED(wlc_hw->wlc); if (dev_gone) { wlc_hw->sbclk = false; wlc_hw->clk = false; wlc_phy_hw_clk_state_upd(wlc_hw->band->pi, false); /* reclaim any posted packets */ wlc_flushqueues(wlc_hw->wlc); } else { /* Reset and disable the core */ if (si_iscoreup(wlc_hw->sih)) { if (R_REG(&wlc_hw->regs->maccontrol) & MCTL_EN_MAC) wlc_suspend_mac_and_wait(wlc_hw->wlc); callbacks += wl_reset(wlc_hw->wlc->wl); wlc_coredisable(wlc_hw); } /* turn off primary xtal and pll */ if (!wlc_hw->noreset) { if (wlc_hw->sih->bustype == PCI_BUS) si_pci_down(wlc_hw->sih); wlc_bmac_xtal(wlc_hw, OFF); } } return callbacks; } void wlc_bmac_wait_for_wake(struct wlc_hw_info *wlc_hw) { /* delay before first read of ucode state */ udelay(40); /* wait until ucode is no longer asleep */ SPINWAIT((wlc_bmac_read_shm(wlc_hw, M_UCODE_DBGST) == DBGST_ASLEEP), wlc_hw->wlc->fastpwrup_dly); ASSERT(wlc_bmac_read_shm(wlc_hw, M_UCODE_DBGST) != DBGST_ASLEEP); } void wlc_bmac_hw_etheraddr(struct wlc_hw_info *wlc_hw, u8 *ea) { memcpy(ea, wlc_hw->etheraddr, ETH_ALEN); } static int wlc_bmac_bandtype(struct wlc_hw_info *wlc_hw) { return wlc_hw->band->bandtype; } /* control chip clock to save power, enable dynamic clock or force fast clock */ static void wlc_clkctl_clk(struct wlc_hw_info *wlc_hw, uint mode) { if (PMUCTL_ENAB(wlc_hw->sih)) { /* new chips with PMU, CCS_FORCEHT will distribute the HT clock on backplane, * but mac core will still run on ALP(not HT) when it enters powersave mode, * which means the FCA bit may not be set. * should wakeup mac if driver wants it to run on HT. */ if (wlc_hw->clk) { if (mode == CLK_FAST) { OR_REG(&wlc_hw->regs->clk_ctl_st, CCS_FORCEHT); udelay(64); SPINWAIT(((R_REG (&wlc_hw->regs-> clk_ctl_st) & CCS_HTAVAIL) == 0), PMU_MAX_TRANSITION_DLY); ASSERT(R_REG (&wlc_hw->regs-> clk_ctl_st) & CCS_HTAVAIL); } else { if ((wlc_hw->sih->pmurev == 0) && (R_REG (&wlc_hw->regs-> clk_ctl_st) & (CCS_FORCEHT | CCS_HTAREQ))) SPINWAIT(((R_REG (&wlc_hw->regs-> clk_ctl_st) & CCS_HTAVAIL) == 0), PMU_MAX_TRANSITION_DLY); AND_REG(&wlc_hw->regs->clk_ctl_st, ~CCS_FORCEHT); } } wlc_hw->forcefastclk = (mode == CLK_FAST); } else { /* old chips w/o PMU, force HT through cc, * then use FCA to verify mac is running fast clock */ wlc_hw->forcefastclk = si_clkctl_cc(wlc_hw->sih, mode); /* check fast clock is available (if core is not in reset) */ if (wlc_hw->forcefastclk && wlc_hw->clk) ASSERT(si_core_sflags(wlc_hw->sih, 0, 0) & SISF_FCLKA); /* keep the ucode wake bit on if forcefastclk is on * since we do not want ucode to put us back to slow clock * when it dozes for PM mode. * Code below matches the wake override bit with current forcefastclk state * Only setting bit in wake_override instead of waking ucode immediately * since old code (wlc.c 1.4499) had this behavior. Older code set * wlc->forcefastclk but only had the wake happen if the wakup_ucode work * (protected by an up check) was executed just below. */ if (wlc_hw->forcefastclk) mboolset(wlc_hw->wake_override, WLC_WAKE_OVERRIDE_FORCEFAST); else mboolclr(wlc_hw->wake_override, WLC_WAKE_OVERRIDE_FORCEFAST); } } /* set initial host flags value */ static void wlc_mhfdef(struct wlc_info *wlc, u16 *mhfs, u16 mhf2_init) { struct wlc_hw_info *wlc_hw = wlc->hw; memset(mhfs, 0, MHFMAX * sizeof(u16)); mhfs[MHF2] |= mhf2_init; /* prohibit use of slowclock on multifunction boards */ if (wlc_hw->boardflags & BFL_NOPLLDOWN) mhfs[MHF1] |= MHF1_FORCEFASTCLK; if (WLCISNPHY(wlc_hw->band) && NREV_LT(wlc_hw->band->phyrev, 2)) { mhfs[MHF2] |= MHF2_NPHY40MHZ_WAR; mhfs[MHF1] |= MHF1_IQSWAP_WAR; } } /* set or clear ucode host flag bits * it has an optimization for no-change write * it only writes through shared memory when the core has clock; * pre-CLK changes should use wlc_write_mhf to get around the optimization * * * bands values are: WLC_BAND_AUTO <--- Current band only * WLC_BAND_5G <--- 5G band only * WLC_BAND_2G <--- 2G band only * WLC_BAND_ALL <--- All bands */ void wlc_bmac_mhf(struct wlc_hw_info *wlc_hw, u8 idx, u16 mask, u16 val, int bands) { u16 save; u16 addr[MHFMAX] = { M_HOST_FLAGS1, M_HOST_FLAGS2, M_HOST_FLAGS3, M_HOST_FLAGS4, M_HOST_FLAGS5 }; struct wlc_hwband *band; ASSERT((val & ~mask) == 0); ASSERT(idx < MHFMAX); ASSERT(ARRAY_SIZE(addr) == MHFMAX); switch (bands) { /* Current band only or all bands, * then set the band to current band */ case WLC_BAND_AUTO: case WLC_BAND_ALL: band = wlc_hw->band; break; case WLC_BAND_5G: band = wlc_hw->bandstate[BAND_5G_INDEX]; break; case WLC_BAND_2G: band = wlc_hw->bandstate[BAND_2G_INDEX]; break; default: ASSERT(0); band = NULL; } if (band) { save = band->mhfs[idx]; band->mhfs[idx] = (band->mhfs[idx] & ~mask) | val; /* optimization: only write through if changed, and * changed band is the current band */ if (wlc_hw->clk && (band->mhfs[idx] != save) && (band == wlc_hw->band)) wlc_bmac_write_shm(wlc_hw, addr[idx], (u16) band->mhfs[idx]); } if (bands == WLC_BAND_ALL) { wlc_hw->bandstate[0]->mhfs[idx] = (wlc_hw->bandstate[0]->mhfs[idx] & ~mask) | val; wlc_hw->bandstate[1]->mhfs[idx] = (wlc_hw->bandstate[1]->mhfs[idx] & ~mask) | val; } } u16 wlc_bmac_mhf_get(struct wlc_hw_info *wlc_hw, u8 idx, int bands) { struct wlc_hwband *band; ASSERT(idx < MHFMAX); switch (bands) { case WLC_BAND_AUTO: band = wlc_hw->band; break; case WLC_BAND_5G: band = wlc_hw->bandstate[BAND_5G_INDEX]; break; case WLC_BAND_2G: band = wlc_hw->bandstate[BAND_2G_INDEX]; break; default: ASSERT(0); band = NULL; } if (!band) return 0; return band->mhfs[idx]; } static void wlc_write_mhf(struct wlc_hw_info *wlc_hw, u16 *mhfs) { u8 idx; u16 addr[] = { M_HOST_FLAGS1, M_HOST_FLAGS2, M_HOST_FLAGS3, M_HOST_FLAGS4, M_HOST_FLAGS5 }; ASSERT(ARRAY_SIZE(addr) == MHFMAX); for (idx = 0; idx < MHFMAX; idx++) { wlc_bmac_write_shm(wlc_hw, addr[idx], mhfs[idx]); } } /* set the maccontrol register to desired reset state and * initialize the sw cache of the register */ static void wlc_mctrl_reset(struct wlc_hw_info *wlc_hw) { /* IHR accesses are always enabled, PSM disabled, HPS off and WAKE on */ wlc_hw->maccontrol = 0; wlc_hw->suspended_fifos = 0; wlc_hw->wake_override = 0; wlc_hw->mute_override = 0; wlc_bmac_mctrl(wlc_hw, ~0, MCTL_IHR_EN | MCTL_WAKE); } /* set or clear maccontrol bits */ void wlc_bmac_mctrl(struct wlc_hw_info *wlc_hw, u32 mask, u32 val) { u32 maccontrol; u32 new_maccontrol; ASSERT((val & ~mask) == 0); maccontrol = wlc_hw->maccontrol; new_maccontrol = (maccontrol & ~mask) | val; /* if the new maccontrol value is the same as the old, nothing to do */ if (new_maccontrol == maccontrol) return; /* something changed, cache the new value */ wlc_hw->maccontrol = new_maccontrol; /* write the new values with overrides applied */ wlc_mctrl_write(wlc_hw); } /* write the software state of maccontrol and overrides to the maccontrol register */ static void wlc_mctrl_write(struct wlc_hw_info *wlc_hw) { u32 maccontrol = wlc_hw->maccontrol; /* OR in the wake bit if overridden */ if (wlc_hw->wake_override) maccontrol |= MCTL_WAKE; /* set AP and INFRA bits for mute if needed */ if (wlc_hw->mute_override) { maccontrol &= ~(MCTL_AP); maccontrol |= MCTL_INFRA; } W_REG(&wlc_hw->regs->maccontrol, maccontrol); } void wlc_ucode_wake_override_set(struct wlc_hw_info *wlc_hw, u32 override_bit) { ASSERT((wlc_hw->wake_override & override_bit) == 0); if (wlc_hw->wake_override || (wlc_hw->maccontrol & MCTL_WAKE)) { mboolset(wlc_hw->wake_override, override_bit); return; } mboolset(wlc_hw->wake_override, override_bit); wlc_mctrl_write(wlc_hw); wlc_bmac_wait_for_wake(wlc_hw); return; } void wlc_ucode_wake_override_clear(struct wlc_hw_info *wlc_hw, u32 override_bit) { ASSERT(wlc_hw->wake_override & override_bit); mboolclr(wlc_hw->wake_override, override_bit); if (wlc_hw->wake_override || (wlc_hw->maccontrol & MCTL_WAKE)) return; wlc_mctrl_write(wlc_hw); return; } /* When driver needs ucode to stop beaconing, it has to make sure that * MCTL_AP is clear and MCTL_INFRA is set * Mode MCTL_AP MCTL_INFRA * AP 1 1 * STA 0 1 <--- This will ensure no beacons * IBSS 0 0 */ static void wlc_ucode_mute_override_set(struct wlc_hw_info *wlc_hw) { wlc_hw->mute_override = 1; /* if maccontrol already has AP == 0 and INFRA == 1 without this * override, then there is no change to write */ if ((wlc_hw->maccontrol & (MCTL_AP | MCTL_INFRA)) == MCTL_INFRA) return; wlc_mctrl_write(wlc_hw); return; } /* Clear the override on AP and INFRA bits */ static void wlc_ucode_mute_override_clear(struct wlc_hw_info *wlc_hw) { if (wlc_hw->mute_override == 0) return; wlc_hw->mute_override = 0; /* if maccontrol already has AP == 0 and INFRA == 1 without this * override, then there is no change to write */ if ((wlc_hw->maccontrol & (MCTL_AP | MCTL_INFRA)) == MCTL_INFRA) return; wlc_mctrl_write(wlc_hw); } /* * Write a MAC address to the rcmta structure */ void wlc_bmac_set_rcmta(struct wlc_hw_info *wlc_hw, int idx, const u8 *addr) { d11regs_t *regs = wlc_hw->regs; volatile u16 *objdata16 = (volatile u16 *)®s->objdata; u32 mac_hm; u16 mac_l; WL_TRACE("wl%d: %s\n", wlc_hw->unit, __func__); mac_hm = (addr[3] << 24) | (addr[2] << 16) | (addr[1] << 8) | addr[0]; mac_l = (addr[5] << 8) | addr[4]; W_REG(®s->objaddr, (OBJADDR_RCMTA_SEL | (idx * 2))); (void)R_REG(®s->objaddr); W_REG(®s->objdata, mac_hm); W_REG(®s->objaddr, (OBJADDR_RCMTA_SEL | ((idx * 2) + 1))); (void)R_REG(®s->objaddr); W_REG(objdata16, mac_l); } /* * Write a MAC address to the given match reg offset in the RXE match engine. */ void wlc_bmac_set_addrmatch(struct wlc_hw_info *wlc_hw, int match_reg_offset, const u8 *addr) { d11regs_t *regs; u16 mac_l; u16 mac_m; u16 mac_h; WL_TRACE("wl%d: wlc_bmac_set_addrmatch\n", wlc_hw->unit); ASSERT(match_reg_offset < RCM_SIZE); regs = wlc_hw->regs; mac_l = addr[0] | (addr[1] << 8); mac_m = addr[2] | (addr[3] << 8); mac_h = addr[4] | (addr[5] << 8); /* enter the MAC addr into the RXE match registers */ W_REG(®s->rcm_ctl, RCM_INC_DATA | match_reg_offset); W_REG(®s->rcm_mat_data, mac_l); W_REG(®s->rcm_mat_data, mac_m); W_REG(®s->rcm_mat_data, mac_h); } void wlc_bmac_write_template_ram(struct wlc_hw_info *wlc_hw, int offset, int len, void *buf) { d11regs_t *regs; u32 word; bool be_bit; #ifdef IL_BIGENDIAN volatile u16 *dptr = NULL; #endif /* IL_BIGENDIAN */ WL_TRACE("wl%d: wlc_bmac_write_template_ram\n", wlc_hw->unit); regs = wlc_hw->regs; ASSERT(IS_ALIGNED(offset, sizeof(u32))); ASSERT(IS_ALIGNED(len, sizeof(u32))); ASSERT((offset & ~0xffff) == 0); W_REG(®s->tplatewrptr, offset); /* if MCTL_BIGEND bit set in mac control register, * the chip swaps data in fifo, as well as data in * template ram */ be_bit = (R_REG(®s->maccontrol) & MCTL_BIGEND) != 0; while (len > 0) { memcpy(&word, buf, sizeof(u32)); if (be_bit) word = cpu_to_be32(word); else word = cpu_to_le32(word); W_REG(®s->tplatewrdata, word); buf = (u8 *) buf + sizeof(u32); len -= sizeof(u32); } } void wlc_bmac_set_cwmin(struct wlc_hw_info *wlc_hw, u16 newmin) { wlc_hw->band->CWmin = newmin; W_REG(&wlc_hw->regs->objaddr, OBJADDR_SCR_SEL | S_DOT11_CWMIN); (void)R_REG(&wlc_hw->regs->objaddr); W_REG(&wlc_hw->regs->objdata, newmin); } void wlc_bmac_set_cwmax(struct wlc_hw_info *wlc_hw, u16 newmax) { wlc_hw->band->CWmax = newmax; W_REG(&wlc_hw->regs->objaddr, OBJADDR_SCR_SEL | S_DOT11_CWMAX); (void)R_REG(&wlc_hw->regs->objaddr); W_REG(&wlc_hw->regs->objdata, newmax); } void wlc_bmac_bw_set(struct wlc_hw_info *wlc_hw, u16 bw) { bool fastclk; /* request FAST clock if not on */ fastclk = wlc_hw->forcefastclk; if (!fastclk) wlc_clkctl_clk(wlc_hw, CLK_FAST); wlc_phy_bw_state_set(wlc_hw->band->pi, bw); ASSERT(wlc_hw->clk); wlc_bmac_phy_reset(wlc_hw); wlc_phy_init(wlc_hw->band->pi, wlc_phy_chanspec_get(wlc_hw->band->pi)); /* restore the clk */ if (!fastclk) wlc_clkctl_clk(wlc_hw, CLK_DYNAMIC); } static void wlc_write_hw_bcntemplate0(struct wlc_hw_info *wlc_hw, void *bcn, int len) { d11regs_t *regs = wlc_hw->regs; wlc_bmac_write_template_ram(wlc_hw, T_BCN0_TPL_BASE, (len + 3) & ~3, bcn); /* write beacon length to SCR */ ASSERT(len < 65536); wlc_bmac_write_shm(wlc_hw, M_BCN0_FRM_BYTESZ, (u16) len); /* mark beacon0 valid */ OR_REG(®s->maccommand, MCMD_BCN0VLD); } static void wlc_write_hw_bcntemplate1(struct wlc_hw_info *wlc_hw, void *bcn, int len) { d11regs_t *regs = wlc_hw->regs; wlc_bmac_write_template_ram(wlc_hw, T_BCN1_TPL_BASE, (len + 3) & ~3, bcn); /* write beacon length to SCR */ ASSERT(len < 65536); wlc_bmac_write_shm(wlc_hw, M_BCN1_FRM_BYTESZ, (u16) len); /* mark beacon1 valid */ OR_REG(®s->maccommand, MCMD_BCN1VLD); } /* mac is assumed to be suspended at this point */ void wlc_bmac_write_hw_bcntemplates(struct wlc_hw_info *wlc_hw, void *bcn, int len, bool both) { d11regs_t *regs = wlc_hw->regs; if (both) { wlc_write_hw_bcntemplate0(wlc_hw, bcn, len); wlc_write_hw_bcntemplate1(wlc_hw, bcn, len); } else { /* bcn 0 */ if (!(R_REG(®s->maccommand) & MCMD_BCN0VLD)) wlc_write_hw_bcntemplate0(wlc_hw, bcn, len); /* bcn 1 */ else if (! (R_REG(®s->maccommand) & MCMD_BCN1VLD)) wlc_write_hw_bcntemplate1(wlc_hw, bcn, len); else /* one template should always have been available */ ASSERT(0); } } static void WLBANDINITFN(wlc_bmac_upd_synthpu) (struct wlc_hw_info *wlc_hw) { u16 v; struct wlc_info *wlc = wlc_hw->wlc; /* update SYNTHPU_DLY */ if (WLCISLCNPHY(wlc->band)) { v = SYNTHPU_DLY_LPPHY_US; } else if (WLCISNPHY(wlc->band) && (NREV_GE(wlc->band->phyrev, 3))) { v = SYNTHPU_DLY_NPHY_US; } else { v = SYNTHPU_DLY_BPHY_US; } wlc_bmac_write_shm(wlc_hw, M_SYNTHPU_DLY, v); } /* band-specific init */ static void WLBANDINITFN(wlc_bmac_bsinit) (struct wlc_info *wlc, chanspec_t chanspec) { struct wlc_hw_info *wlc_hw = wlc->hw; WL_TRACE("wl%d: wlc_bmac_bsinit: bandunit %d\n", wlc_hw->unit, wlc_hw->band->bandunit); /* sanity check */ if (PHY_TYPE(R_REG(&wlc_hw->regs->phyversion)) != PHY_TYPE_LCNXN) ASSERT((uint) PHY_TYPE(R_REG(&wlc_hw->regs->phyversion)) == wlc_hw->band->phytype); wlc_ucode_bsinit(wlc_hw); wlc_phy_init(wlc_hw->band->pi, chanspec); wlc_ucode_txant_set(wlc_hw); /* cwmin is band-specific, update hardware with value for current band */ wlc_bmac_set_cwmin(wlc_hw, wlc_hw->band->CWmin); wlc_bmac_set_cwmax(wlc_hw, wlc_hw->band->CWmax); wlc_bmac_update_slot_timing(wlc_hw, BAND_5G(wlc_hw->band-> bandtype) ? true : wlc_hw-> shortslot); /* write phytype and phyvers */ wlc_bmac_write_shm(wlc_hw, M_PHYTYPE, (u16) wlc_hw->band->phytype); wlc_bmac_write_shm(wlc_hw, M_PHYVER, (u16) wlc_hw->band->phyrev); /* initialize the txphyctl1 rate table since shmem is shared between bands */ wlc_upd_ofdm_pctl1_table(wlc_hw); wlc_bmac_upd_synthpu(wlc_hw); } static void wlc_bmac_core_phy_clk(struct wlc_hw_info *wlc_hw, bool clk) { WL_TRACE("wl%d: wlc_bmac_core_phy_clk: clk %d\n", wlc_hw->unit, clk); wlc_hw->phyclk = clk; if (OFF == clk) { /* clear gmode bit, put phy into reset */ si_core_cflags(wlc_hw->sih, (SICF_PRST | SICF_FGC | SICF_GMODE), (SICF_PRST | SICF_FGC)); udelay(1); si_core_cflags(wlc_hw->sih, (SICF_PRST | SICF_FGC), SICF_PRST); udelay(1); } else { /* take phy out of reset */ si_core_cflags(wlc_hw->sih, (SICF_PRST | SICF_FGC), SICF_FGC); udelay(1); si_core_cflags(wlc_hw->sih, (SICF_FGC), 0); udelay(1); } } /* Perform a soft reset of the PHY PLL */ void wlc_bmac_core_phypll_reset(struct wlc_hw_info *wlc_hw) { WL_TRACE("wl%d: wlc_bmac_core_phypll_reset\n", wlc_hw->unit); si_corereg(wlc_hw->sih, SI_CC_IDX, offsetof(chipcregs_t, chipcontrol_addr), ~0, 0); udelay(1); si_corereg(wlc_hw->sih, SI_CC_IDX, offsetof(chipcregs_t, chipcontrol_data), 0x4, 0); udelay(1); si_corereg(wlc_hw->sih, SI_CC_IDX, offsetof(chipcregs_t, chipcontrol_data), 0x4, 4); udelay(1); si_corereg(wlc_hw->sih, SI_CC_IDX, offsetof(chipcregs_t, chipcontrol_data), 0x4, 0); udelay(1); } /* light way to turn on phy clock without reset for NPHY only * refer to wlc_bmac_core_phy_clk for full version */ void wlc_bmac_phyclk_fgc(struct wlc_hw_info *wlc_hw, bool clk) { /* support(necessary for NPHY and HYPHY) only */ if (!WLCISNPHY(wlc_hw->band)) return; if (ON == clk) si_core_cflags(wlc_hw->sih, SICF_FGC, SICF_FGC); else si_core_cflags(wlc_hw->sih, SICF_FGC, 0); } void wlc_bmac_macphyclk_set(struct wlc_hw_info *wlc_hw, bool clk) { if (ON == clk) si_core_cflags(wlc_hw->sih, SICF_MPCLKE, SICF_MPCLKE); else si_core_cflags(wlc_hw->sih, SICF_MPCLKE, 0); } void wlc_bmac_phy_reset(struct wlc_hw_info *wlc_hw) { wlc_phy_t *pih = wlc_hw->band->pi; u32 phy_bw_clkbits; bool phy_in_reset = false; WL_TRACE("wl%d: wlc_bmac_phy_reset\n", wlc_hw->unit); if (pih == NULL) return; phy_bw_clkbits = wlc_phy_clk_bwbits(wlc_hw->band->pi); /* Specific reset sequence required for NPHY rev 3 and 4 */ if (WLCISNPHY(wlc_hw->band) && NREV_GE(wlc_hw->band->phyrev, 3) && NREV_LE(wlc_hw->band->phyrev, 4)) { /* Set the PHY bandwidth */ si_core_cflags(wlc_hw->sih, SICF_BWMASK, phy_bw_clkbits); udelay(1); /* Perform a soft reset of the PHY PLL */ wlc_bmac_core_phypll_reset(wlc_hw); /* reset the PHY */ si_core_cflags(wlc_hw->sih, (SICF_PRST | SICF_PCLKE), (SICF_PRST | SICF_PCLKE)); phy_in_reset = true; } else { si_core_cflags(wlc_hw->sih, (SICF_PRST | SICF_PCLKE | SICF_BWMASK), (SICF_PRST | SICF_PCLKE | phy_bw_clkbits)); } udelay(2); wlc_bmac_core_phy_clk(wlc_hw, ON); if (pih) wlc_phy_anacore(pih, ON); } /* switch to and initialize new band */ static void WLBANDINITFN(wlc_bmac_setband) (struct wlc_hw_info *wlc_hw, uint bandunit, chanspec_t chanspec) { struct wlc_info *wlc = wlc_hw->wlc; u32 macintmask; ASSERT(NBANDS_HW(wlc_hw) > 1); ASSERT(bandunit != wlc_hw->band->bandunit); /* Enable the d11 core before accessing it */ if (!si_iscoreup(wlc_hw->sih)) { si_core_reset(wlc_hw->sih, 0, 0); ASSERT(si_iscoreup(wlc_hw->sih)); wlc_mctrl_reset(wlc_hw); } macintmask = wlc_setband_inact(wlc, bandunit); if (!wlc_hw->up) return; wlc_bmac_core_phy_clk(wlc_hw, ON); /* band-specific initializations */ wlc_bmac_bsinit(wlc, chanspec); /* * If there are any pending software interrupt bits, * then replace these with a harmless nonzero value * so wlc_dpc() will re-enable interrupts when done. */ if (wlc->macintstatus) wlc->macintstatus = MI_DMAINT; /* restore macintmask */ wl_intrsrestore(wlc->wl, macintmask); /* ucode should still be suspended.. */ ASSERT((R_REG(&wlc_hw->regs->maccontrol) & MCTL_EN_MAC) == 0); } /* low-level band switch utility routine */ void WLBANDINITFN(wlc_setxband) (struct wlc_hw_info *wlc_hw, uint bandunit) { WL_TRACE("wl%d: wlc_setxband: bandunit %d\n", wlc_hw->unit, bandunit); wlc_hw->band = wlc_hw->bandstate[bandunit]; /* BMAC_NOTE: until we eliminate need for wlc->band refs in low level code */ wlc_hw->wlc->band = wlc_hw->wlc->bandstate[bandunit]; /* set gmode core flag */ if (wlc_hw->sbclk && !wlc_hw->noreset) { si_core_cflags(wlc_hw->sih, SICF_GMODE, ((bandunit == 0) ? SICF_GMODE : 0)); } } static bool wlc_isgoodchip(struct wlc_hw_info *wlc_hw) { /* reject unsupported corerev */ if (!VALID_COREREV(wlc_hw->corerev)) { WL_ERROR("unsupported core rev %d\n", wlc_hw->corerev); return false; } return true; } static bool wlc_validboardtype(struct wlc_hw_info *wlc_hw) { bool goodboard = true; uint boardrev = wlc_hw->boardrev; if (boardrev == 0) goodboard = false; else if (boardrev > 0xff) { uint brt = (boardrev & 0xf000) >> 12; uint b0 = (boardrev & 0xf00) >> 8; uint b1 = (boardrev & 0xf0) >> 4; uint b2 = boardrev & 0xf; if ((brt > 2) || (brt == 0) || (b0 > 9) || (b0 == 0) || (b1 > 9) || (b2 > 9)) goodboard = false; } if (wlc_hw->sih->boardvendor != VENDOR_BROADCOM) return goodboard; return goodboard; } static char *wlc_get_macaddr(struct wlc_hw_info *wlc_hw) { const char *varname = "macaddr"; char *macaddr; /* If macaddr exists, use it (Sromrev4, CIS, ...). */ macaddr = getvar(wlc_hw->vars, varname); if (macaddr != NULL) return macaddr; if (NBANDS_HW(wlc_hw) > 1) varname = "et1macaddr"; else varname = "il0macaddr"; macaddr = getvar(wlc_hw->vars, varname); if (macaddr == NULL) { WL_ERROR("wl%d: wlc_get_macaddr: macaddr getvar(%s) not found\n", wlc_hw->unit, varname); } return macaddr; } /* * Return true if radio is disabled, otherwise false. * hw radio disable signal is an external pin, users activate it asynchronously * this function could be called when driver is down and w/o clock * it operates on different registers depending on corerev and boardflag. */ bool wlc_bmac_radio_read_hwdisabled(struct wlc_hw_info *wlc_hw) { bool v, clk, xtal; u32 resetbits = 0, flags = 0; xtal = wlc_hw->sbclk; if (!xtal) wlc_bmac_xtal(wlc_hw, ON); /* may need to take core out of reset first */ clk = wlc_hw->clk; if (!clk) { /* * mac no longer enables phyclk automatically when driver * accesses phyreg throughput mac. This can be skipped since * only mac reg is accessed below */ flags |= SICF_PCLKE; /* AI chip doesn't restore bar0win2 on hibernation/resume, need sw fixup */ if ((wlc_hw->sih->chip == BCM43224_CHIP_ID) || (wlc_hw->sih->chip == BCM43225_CHIP_ID) || (wlc_hw->sih->chip == BCM43421_CHIP_ID)) wlc_hw->regs = (d11regs_t *) si_setcore(wlc_hw->sih, D11_CORE_ID, 0); si_core_reset(wlc_hw->sih, flags, resetbits); wlc_mctrl_reset(wlc_hw); } v = ((R_REG(&wlc_hw->regs->phydebug) & PDBG_RFD) != 0); /* put core back into reset */ if (!clk) si_core_disable(wlc_hw->sih, 0); if (!xtal) wlc_bmac_xtal(wlc_hw, OFF); return v; } /* Initialize just the hardware when coming out of POR or S3/S5 system states */ void wlc_bmac_hw_up(struct wlc_hw_info *wlc_hw) { if (wlc_hw->wlc->pub->hw_up) return; WL_TRACE("wl%d: %s:\n", wlc_hw->unit, __func__); /* * Enable pll and xtal, initialize the power control registers, * and force fastclock for the remainder of wlc_up(). */ wlc_bmac_xtal(wlc_hw, ON); si_clkctl_init(wlc_hw->sih); wlc_clkctl_clk(wlc_hw, CLK_FAST); if (wlc_hw->sih->bustype == PCI_BUS) { si_pci_fixcfg(wlc_hw->sih); /* AI chip doesn't restore bar0win2 on hibernation/resume, need sw fixup */ if ((wlc_hw->sih->chip == BCM43224_CHIP_ID) || (wlc_hw->sih->chip == BCM43225_CHIP_ID) || (wlc_hw->sih->chip == BCM43421_CHIP_ID)) wlc_hw->regs = (d11regs_t *) si_setcore(wlc_hw->sih, D11_CORE_ID, 0); } /* Inform phy that a POR reset has occurred so it does a complete phy init */ wlc_phy_por_inform(wlc_hw->band->pi); wlc_hw->ucode_loaded = false; wlc_hw->wlc->pub->hw_up = true; if ((wlc_hw->boardflags & BFL_FEM) && (wlc_hw->sih->chip == BCM4313_CHIP_ID)) { if (! (wlc_hw->boardrev >= 0x1250 && (wlc_hw->boardflags & BFL_FEM_BT))) si_epa_4313war(wlc_hw->sih); } } static bool wlc_dma_rxreset(struct wlc_hw_info *wlc_hw, uint fifo) { struct hnddma_pub *di = wlc_hw->di[fifo]; return dma_rxreset(di); } /* d11 core reset * ensure fask clock during reset * reset dma * reset d11(out of reset) * reset phy(out of reset) * clear software macintstatus for fresh new start * one testing hack wlc_hw->noreset will bypass the d11/phy reset */ void wlc_bmac_corereset(struct wlc_hw_info *wlc_hw, u32 flags) { d11regs_t *regs; uint i; bool fastclk; u32 resetbits = 0; if (flags == WLC_USE_COREFLAGS) flags = (wlc_hw->band->pi ? wlc_hw->band->core_flags : 0); WL_TRACE("wl%d: %s\n", wlc_hw->unit, __func__); regs = wlc_hw->regs; /* request FAST clock if not on */ fastclk = wlc_hw->forcefastclk; if (!fastclk) wlc_clkctl_clk(wlc_hw, CLK_FAST); /* reset the dma engines except first time thru */ if (si_iscoreup(wlc_hw->sih)) { for (i = 0; i < NFIFO; i++) if ((wlc_hw->di[i]) && (!dma_txreset(wlc_hw->di[i]))) { WL_ERROR("wl%d: %s: dma_txreset[%d]: cannot stop dma\n", wlc_hw->unit, __func__, i); } if ((wlc_hw->di[RX_FIFO]) && (!wlc_dma_rxreset(wlc_hw, RX_FIFO))) { WL_ERROR("wl%d: %s: dma_rxreset[%d]: cannot stop dma\n", wlc_hw->unit, __func__, RX_FIFO); } } /* if noreset, just stop the psm and return */ if (wlc_hw->noreset) { wlc_hw->wlc->macintstatus = 0; /* skip wl_dpc after down */ wlc_bmac_mctrl(wlc_hw, MCTL_PSM_RUN | MCTL_EN_MAC, 0); return; } /* * mac no longer enables phyclk automatically when driver accesses * phyreg throughput mac, AND phy_reset is skipped at early stage when * band->pi is invalid. need to enable PHY CLK */ flags |= SICF_PCLKE; /* reset the core * In chips with PMU, the fastclk request goes through d11 core reg 0x1e0, which * is cleared by the core_reset. have to re-request it. * This adds some delay and we can optimize it by also requesting fastclk through * chipcommon during this period if necessary. But that has to work coordinate * with other driver like mips/arm since they may touch chipcommon as well. */ wlc_hw->clk = false; si_core_reset(wlc_hw->sih, flags, resetbits); wlc_hw->clk = true; if (wlc_hw->band && wlc_hw->band->pi) wlc_phy_hw_clk_state_upd(wlc_hw->band->pi, true); wlc_mctrl_reset(wlc_hw); if (PMUCTL_ENAB(wlc_hw->sih)) wlc_clkctl_clk(wlc_hw, CLK_FAST); wlc_bmac_phy_reset(wlc_hw); /* turn on PHY_PLL */ wlc_bmac_core_phypll_ctl(wlc_hw, true); /* clear sw intstatus */ wlc_hw->wlc->macintstatus = 0; /* restore the clk setting */ if (!fastclk) wlc_clkctl_clk(wlc_hw, CLK_DYNAMIC); } /* txfifo sizes needs to be modified(increased) since the newer cores * have more memory. */ static void wlc_corerev_fifofixup(struct wlc_hw_info *wlc_hw) { d11regs_t *regs = wlc_hw->regs; u16 fifo_nu; u16 txfifo_startblk = TXFIFO_START_BLK, txfifo_endblk; u16 txfifo_def, txfifo_def1; u16 txfifo_cmd; /* tx fifos start at TXFIFO_START_BLK from the Base address */ txfifo_startblk = TXFIFO_START_BLK; /* sequence of operations: reset fifo, set fifo size, reset fifo */ for (fifo_nu = 0; fifo_nu < NFIFO; fifo_nu++) { txfifo_endblk = txfifo_startblk + wlc_hw->xmtfifo_sz[fifo_nu]; txfifo_def = (txfifo_startblk & 0xff) | (((txfifo_endblk - 1) & 0xff) << TXFIFO_FIFOTOP_SHIFT); txfifo_def1 = ((txfifo_startblk >> 8) & 0x1) | ((((txfifo_endblk - 1) >> 8) & 0x1) << TXFIFO_FIFOTOP_SHIFT); txfifo_cmd = TXFIFOCMD_RESET_MASK | (fifo_nu << TXFIFOCMD_FIFOSEL_SHIFT); W_REG(®s->xmtfifocmd, txfifo_cmd); W_REG(®s->xmtfifodef, txfifo_def); W_REG(®s->xmtfifodef1, txfifo_def1); W_REG(®s->xmtfifocmd, txfifo_cmd); txfifo_startblk += wlc_hw->xmtfifo_sz[fifo_nu]; } /* * need to propagate to shm location to be in sync since ucode/hw won't * do this */ wlc_bmac_write_shm(wlc_hw, M_FIFOSIZE0, wlc_hw->xmtfifo_sz[TX_AC_BE_FIFO]); wlc_bmac_write_shm(wlc_hw, M_FIFOSIZE1, wlc_hw->xmtfifo_sz[TX_AC_VI_FIFO]); wlc_bmac_write_shm(wlc_hw, M_FIFOSIZE2, ((wlc_hw->xmtfifo_sz[TX_AC_VO_FIFO] << 8) | wlc_hw-> xmtfifo_sz[TX_AC_BK_FIFO])); wlc_bmac_write_shm(wlc_hw, M_FIFOSIZE3, ((wlc_hw->xmtfifo_sz[TX_ATIM_FIFO] << 8) | wlc_hw-> xmtfifo_sz[TX_BCMC_FIFO])); } /* d11 core init * reset PSM * download ucode/PCM * let ucode run to suspended * download ucode inits * config other core registers * init dma */ static void wlc_coreinit(struct wlc_info *wlc) { struct wlc_hw_info *wlc_hw = wlc->hw; d11regs_t *regs; u32 sflags; uint bcnint_us; uint i = 0; bool fifosz_fixup = false; int err = 0; u16 buf[NFIFO]; regs = wlc_hw->regs; WL_TRACE("wl%d: wlc_coreinit\n", wlc_hw->unit); /* reset PSM */ wlc_bmac_mctrl(wlc_hw, ~0, (MCTL_IHR_EN | MCTL_PSM_JMP_0 | MCTL_WAKE)); wlc_ucode_download(wlc_hw); /* * FIFOSZ fixup. driver wants to controls the fifo allocation. */ fifosz_fixup = true; /* let the PSM run to the suspended state, set mode to BSS STA */ W_REG(®s->macintstatus, -1); wlc_bmac_mctrl(wlc_hw, ~0, (MCTL_IHR_EN | MCTL_INFRA | MCTL_PSM_RUN | MCTL_WAKE)); /* wait for ucode to self-suspend after auto-init */ SPINWAIT(((R_REG(®s->macintstatus) & MI_MACSSPNDD) == 0), 1000 * 1000); if ((R_REG(®s->macintstatus) & MI_MACSSPNDD) == 0) WL_ERROR("wl%d: wlc_coreinit: ucode did not self-suspend!\n", wlc_hw->unit); wlc_gpio_init(wlc); sflags = si_core_sflags(wlc_hw->sih, 0, 0); if (D11REV_IS(wlc_hw->corerev, 23)) { if (WLCISNPHY(wlc_hw->band)) wlc_write_inits(wlc_hw, d11n0initvals16); else WL_ERROR("%s: wl%d: unsupported phy in corerev %d\n", __func__, wlc_hw->unit, wlc_hw->corerev); } else if (D11REV_IS(wlc_hw->corerev, 24)) { if (WLCISLCNPHY(wlc_hw->band)) { wlc_write_inits(wlc_hw, d11lcn0initvals24); } else { WL_ERROR("%s: wl%d: unsupported phy in corerev %d\n", __func__, wlc_hw->unit, wlc_hw->corerev); } } else { WL_ERROR("%s: wl%d: unsupported corerev %d\n", __func__, wlc_hw->unit, wlc_hw->corerev); } /* For old ucode, txfifo sizes needs to be modified(increased) */ if (fifosz_fixup == true) { wlc_corerev_fifofixup(wlc_hw); } /* check txfifo allocations match between ucode and driver */ buf[TX_AC_BE_FIFO] = wlc_bmac_read_shm(wlc_hw, M_FIFOSIZE0); if (buf[TX_AC_BE_FIFO] != wlc_hw->xmtfifo_sz[TX_AC_BE_FIFO]) { i = TX_AC_BE_FIFO; err = -1; } buf[TX_AC_VI_FIFO] = wlc_bmac_read_shm(wlc_hw, M_FIFOSIZE1); if (buf[TX_AC_VI_FIFO] != wlc_hw->xmtfifo_sz[TX_AC_VI_FIFO]) { i = TX_AC_VI_FIFO; err = -1; } buf[TX_AC_BK_FIFO] = wlc_bmac_read_shm(wlc_hw, M_FIFOSIZE2); buf[TX_AC_VO_FIFO] = (buf[TX_AC_BK_FIFO] >> 8) & 0xff; buf[TX_AC_BK_FIFO] &= 0xff; if (buf[TX_AC_BK_FIFO] != wlc_hw->xmtfifo_sz[TX_AC_BK_FIFO]) { i = TX_AC_BK_FIFO; err = -1; } if (buf[TX_AC_VO_FIFO] != wlc_hw->xmtfifo_sz[TX_AC_VO_FIFO]) { i = TX_AC_VO_FIFO; err = -1; } buf[TX_BCMC_FIFO] = wlc_bmac_read_shm(wlc_hw, M_FIFOSIZE3); buf[TX_ATIM_FIFO] = (buf[TX_BCMC_FIFO] >> 8) & 0xff; buf[TX_BCMC_FIFO] &= 0xff; if (buf[TX_BCMC_FIFO] != wlc_hw->xmtfifo_sz[TX_BCMC_FIFO]) { i = TX_BCMC_FIFO; err = -1; } if (buf[TX_ATIM_FIFO] != wlc_hw->xmtfifo_sz[TX_ATIM_FIFO]) { i = TX_ATIM_FIFO; err = -1; } if (err != 0) { WL_ERROR("wlc_coreinit: txfifo mismatch: ucode size %d driver size %d index %d\n", buf[i], wlc_hw->xmtfifo_sz[i], i); ASSERT(0); } /* make sure we can still talk to the mac */ ASSERT(R_REG(®s->maccontrol) != 0xffffffff); /* band-specific inits done by wlc_bsinit() */ /* Set up frame burst size and antenna swap threshold init values */ wlc_bmac_write_shm(wlc_hw, M_MBURST_SIZE, MAXTXFRAMEBURST); wlc_bmac_write_shm(wlc_hw, M_MAX_ANTCNT, ANTCNT); /* enable one rx interrupt per received frame */ W_REG(®s->intrcvlazy[0], (1 << IRL_FC_SHIFT)); /* set the station mode (BSS STA) */ wlc_bmac_mctrl(wlc_hw, (MCTL_INFRA | MCTL_DISCARD_PMQ | MCTL_AP), (MCTL_INFRA | MCTL_DISCARD_PMQ)); /* set up Beacon interval */ bcnint_us = 0x8000 << 10; W_REG(®s->tsf_cfprep, (bcnint_us << CFPREP_CBI_SHIFT)); W_REG(®s->tsf_cfpstart, bcnint_us); W_REG(®s->macintstatus, MI_GP1); /* write interrupt mask */ W_REG(®s->intctrlregs[RX_FIFO].intmask, DEF_RXINTMASK); /* allow the MAC to control the PHY clock (dynamic on/off) */ wlc_bmac_macphyclk_set(wlc_hw, ON); /* program dynamic clock control fast powerup delay register */ wlc->fastpwrup_dly = si_clkctl_fast_pwrup_delay(wlc_hw->sih); W_REG(®s->scc_fastpwrup_dly, wlc->fastpwrup_dly); /* tell the ucode the corerev */ wlc_bmac_write_shm(wlc_hw, M_MACHW_VER, (u16) wlc_hw->corerev); /* tell the ucode MAC capabilities */ wlc_bmac_write_shm(wlc_hw, M_MACHW_CAP_L, (u16) (wlc_hw->machwcap & 0xffff)); wlc_bmac_write_shm(wlc_hw, M_MACHW_CAP_H, (u16) ((wlc_hw-> machwcap >> 16) & 0xffff)); /* write retry limits to SCR, this done after PSM init */ W_REG(®s->objaddr, OBJADDR_SCR_SEL | S_DOT11_SRC_LMT); (void)R_REG(®s->objaddr); W_REG(®s->objdata, wlc_hw->SRL); W_REG(®s->objaddr, OBJADDR_SCR_SEL | S_DOT11_LRC_LMT); (void)R_REG(®s->objaddr); W_REG(®s->objdata, wlc_hw->LRL); /* write rate fallback retry limits */ wlc_bmac_write_shm(wlc_hw, M_SFRMTXCNTFBRTHSD, wlc_hw->SFBL); wlc_bmac_write_shm(wlc_hw, M_LFRMTXCNTFBRTHSD, wlc_hw->LFBL); AND_REG(®s->ifs_ctl, 0x0FFF); W_REG(®s->ifs_aifsn, EDCF_AIFSN_MIN); /* dma initializations */ wlc->txpend16165war = 0; /* init the tx dma engines */ for (i = 0; i < NFIFO; i++) { if (wlc_hw->di[i]) dma_txinit(wlc_hw->di[i]); } /* init the rx dma engine(s) and post receive buffers */ dma_rxinit(wlc_hw->di[RX_FIFO]); dma_rxfill(wlc_hw->di[RX_FIFO]); } /* This function is used for changing the tsf frac register * If spur avoidance mode is off, the mac freq will be 80/120/160Mhz * If spur avoidance mode is on1, the mac freq will be 82/123/164Mhz * If spur avoidance mode is on2, the mac freq will be 84/126/168Mhz * HTPHY Formula is 2^26/freq(MHz) e.g. * For spuron2 - 126MHz -> 2^26/126 = 532610.0 * - 532610 = 0x82082 => tsf_clk_frac_h = 0x8, tsf_clk_frac_l = 0x2082 * For spuron: 123MHz -> 2^26/123 = 545600.5 * - 545601 = 0x85341 => tsf_clk_frac_h = 0x8, tsf_clk_frac_l = 0x5341 * For spur off: 120MHz -> 2^26/120 = 559240.5 * - 559241 = 0x88889 => tsf_clk_frac_h = 0x8, tsf_clk_frac_l = 0x8889 */ void wlc_bmac_switch_macfreq(struct wlc_hw_info *wlc_hw, u8 spurmode) { d11regs_t *regs; regs = wlc_hw->regs; if ((wlc_hw->sih->chip == BCM43224_CHIP_ID) || (wlc_hw->sih->chip == BCM43225_CHIP_ID)) { if (spurmode == WL_SPURAVOID_ON2) { /* 126Mhz */ W_REG(®s->tsf_clk_frac_l, 0x2082); W_REG(®s->tsf_clk_frac_h, 0x8); } else if (spurmode == WL_SPURAVOID_ON1) { /* 123Mhz */ W_REG(®s->tsf_clk_frac_l, 0x5341); W_REG(®s->tsf_clk_frac_h, 0x8); } else { /* 120Mhz */ W_REG(®s->tsf_clk_frac_l, 0x8889); W_REG(®s->tsf_clk_frac_h, 0x8); } } else if (WLCISLCNPHY(wlc_hw->band)) { if (spurmode == WL_SPURAVOID_ON1) { /* 82Mhz */ W_REG(®s->tsf_clk_frac_l, 0x7CE0); W_REG(®s->tsf_clk_frac_h, 0xC); } else { /* 80Mhz */ W_REG(®s->tsf_clk_frac_l, 0xCCCD); W_REG(®s->tsf_clk_frac_h, 0xC); } } } /* Initialize GPIOs that are controlled by D11 core */ static void wlc_gpio_init(struct wlc_info *wlc) { struct wlc_hw_info *wlc_hw = wlc->hw; d11regs_t *regs; u32 gc, gm; regs = wlc_hw->regs; /* use GPIO select 0 to get all gpio signals from the gpio out reg */ wlc_bmac_mctrl(wlc_hw, MCTL_GPOUT_SEL_MASK, 0); /* * Common GPIO setup: * G0 = LED 0 = WLAN Activity * G1 = LED 1 = WLAN 2.4 GHz Radio State * G2 = LED 2 = WLAN 5 GHz Radio State * G4 = radio disable input (HI enabled, LO disabled) */ gc = gm = 0; /* Allocate GPIOs for mimo antenna diversity feature */ if (wlc_hw->antsel_type == ANTSEL_2x3) { /* Enable antenna diversity, use 2x3 mode */ wlc_bmac_mhf(wlc_hw, MHF3, MHF3_ANTSEL_EN, MHF3_ANTSEL_EN, WLC_BAND_ALL); wlc_bmac_mhf(wlc_hw, MHF3, MHF3_ANTSEL_MODE, MHF3_ANTSEL_MODE, WLC_BAND_ALL); /* init superswitch control */ wlc_phy_antsel_init(wlc_hw->band->pi, false); } else if (wlc_hw->antsel_type == ANTSEL_2x4) { ASSERT((gm & BOARD_GPIO_12) == 0); gm |= gc |= (BOARD_GPIO_12 | BOARD_GPIO_13); /* * The board itself is powered by these GPIOs * (when not sending pattern) so set them high */ OR_REG(®s->psm_gpio_oe, (BOARD_GPIO_12 | BOARD_GPIO_13)); OR_REG(®s->psm_gpio_out, (BOARD_GPIO_12 | BOARD_GPIO_13)); /* Enable antenna diversity, use 2x4 mode */ wlc_bmac_mhf(wlc_hw, MHF3, MHF3_ANTSEL_EN, MHF3_ANTSEL_EN, WLC_BAND_ALL); wlc_bmac_mhf(wlc_hw, MHF3, MHF3_ANTSEL_MODE, 0, WLC_BAND_ALL); /* Configure the desired clock to be 4Mhz */ wlc_bmac_write_shm(wlc_hw, M_ANTSEL_CLKDIV, ANTSEL_CLKDIV_4MHZ); } /* gpio 9 controls the PA. ucode is responsible for wiggling out and oe */ if (wlc_hw->boardflags & BFL_PACTRL) gm |= gc |= BOARD_GPIO_PACTRL; /* apply to gpiocontrol register */ si_gpiocontrol(wlc_hw->sih, gm, gc, GPIO_DRV_PRIORITY); } static void wlc_ucode_download(struct wlc_hw_info *wlc_hw) { struct wlc_info *wlc; wlc = wlc_hw->wlc; if (wlc_hw->ucode_loaded) return; if (D11REV_IS(wlc_hw->corerev, 23)) { if (WLCISNPHY(wlc_hw->band)) { wlc_ucode_write(wlc_hw, bcm43xx_16_mimo, bcm43xx_16_mimosz); wlc_hw->ucode_loaded = true; } else WL_ERROR("%s: wl%d: unsupported phy in corerev %d\n", __func__, wlc_hw->unit, wlc_hw->corerev); } else if (D11REV_IS(wlc_hw->corerev, 24)) { if (WLCISLCNPHY(wlc_hw->band)) { wlc_ucode_write(wlc_hw, bcm43xx_24_lcn, bcm43xx_24_lcnsz); wlc_hw->ucode_loaded = true; } else { WL_ERROR("%s: wl%d: unsupported phy in corerev %d\n", __func__, wlc_hw->unit, wlc_hw->corerev); } } } static void wlc_ucode_write(struct wlc_hw_info *wlc_hw, const u32 ucode[], const uint nbytes) { d11regs_t *regs = wlc_hw->regs; uint i; uint count; WL_TRACE("wl%d: wlc_ucode_write\n", wlc_hw->unit); ASSERT(IS_ALIGNED(nbytes, sizeof(u32))); count = (nbytes / sizeof(u32)); W_REG(®s->objaddr, (OBJADDR_AUTO_INC | OBJADDR_UCM_SEL)); (void)R_REG(®s->objaddr); for (i = 0; i < count; i++) W_REG(®s->objdata, ucode[i]); } static void wlc_write_inits(struct wlc_hw_info *wlc_hw, const struct d11init *inits) { int i; volatile u8 *base; WL_TRACE("wl%d: wlc_write_inits\n", wlc_hw->unit); base = (volatile u8 *)wlc_hw->regs; for (i = 0; inits[i].addr != 0xffff; i++) { ASSERT((inits[i].size == 2) || (inits[i].size == 4)); if (inits[i].size == 2) W_REG((u16 *)(base + inits[i].addr), inits[i].value); else if (inits[i].size == 4) W_REG((u32 *)(base + inits[i].addr), inits[i].value); } } static void wlc_ucode_txant_set(struct wlc_hw_info *wlc_hw) { u16 phyctl; u16 phytxant = wlc_hw->bmac_phytxant; u16 mask = PHY_TXC_ANT_MASK; /* set the Probe Response frame phy control word */ phyctl = wlc_bmac_read_shm(wlc_hw, M_CTXPRS_BLK + C_CTX_PCTLWD_POS); phyctl = (phyctl & ~mask) | phytxant; wlc_bmac_write_shm(wlc_hw, M_CTXPRS_BLK + C_CTX_PCTLWD_POS, phyctl); /* set the Response (ACK/CTS) frame phy control word */ phyctl = wlc_bmac_read_shm(wlc_hw, M_RSP_PCTLWD); phyctl = (phyctl & ~mask) | phytxant; wlc_bmac_write_shm(wlc_hw, M_RSP_PCTLWD, phyctl); } void wlc_bmac_txant_set(struct wlc_hw_info *wlc_hw, u16 phytxant) { /* update sw state */ wlc_hw->bmac_phytxant = phytxant; /* push to ucode if up */ if (!wlc_hw->up) return; wlc_ucode_txant_set(wlc_hw); } u16 wlc_bmac_get_txant(struct wlc_hw_info *wlc_hw) { return (u16) wlc_hw->wlc->stf->txant; } void wlc_bmac_antsel_type_set(struct wlc_hw_info *wlc_hw, u8 antsel_type) { wlc_hw->antsel_type = antsel_type; /* Update the antsel type for phy module to use */ wlc_phy_antsel_type_set(wlc_hw->band->pi, antsel_type); } void wlc_bmac_fifoerrors(struct wlc_hw_info *wlc_hw) { bool fatal = false; uint unit; uint intstatus, idx; d11regs_t *regs = wlc_hw->regs; unit = wlc_hw->unit; for (idx = 0; idx < NFIFO; idx++) { /* read intstatus register and ignore any non-error bits */ intstatus = R_REG(®s->intctrlregs[idx].intstatus) & I_ERRORS; if (!intstatus) continue; WL_TRACE("wl%d: wlc_bmac_fifoerrors: intstatus%d 0x%x\n", unit, idx, intstatus); if (intstatus & I_RO) { WL_ERROR("wl%d: fifo %d: receive fifo overflow\n", unit, idx); wlc_hw->wlc->pub->_cnt->rxoflo++; fatal = true; } if (intstatus & I_PC) { WL_ERROR("wl%d: fifo %d: descriptor error\n", unit, idx); wlc_hw->wlc->pub->_cnt->dmade++; fatal = true; } if (intstatus & I_PD) { WL_ERROR("wl%d: fifo %d: data error\n", unit, idx); wlc_hw->wlc->pub->_cnt->dmada++; fatal = true; } if (intstatus & I_DE) { WL_ERROR("wl%d: fifo %d: descriptor protocol error\n", unit, idx); wlc_hw->wlc->pub->_cnt->dmape++; fatal = true; } if (intstatus & I_RU) { WL_ERROR("wl%d: fifo %d: receive descriptor underflow\n", idx, unit); wlc_hw->wlc->pub->_cnt->rxuflo[idx]++; } if (intstatus & I_XU) { WL_ERROR("wl%d: fifo %d: transmit fifo underflow\n", idx, unit); wlc_hw->wlc->pub->_cnt->txuflo++; fatal = true; } if (fatal) { wlc_fatal_error(wlc_hw->wlc); /* big hammer */ break; } else W_REG(®s->intctrlregs[idx].intstatus, intstatus); } } void wlc_intrson(struct wlc_info *wlc) { struct wlc_hw_info *wlc_hw = wlc->hw; ASSERT(wlc->defmacintmask); wlc->macintmask = wlc->defmacintmask; W_REG(&wlc_hw->regs->macintmask, wlc->macintmask); } /* callback for siutils.c, which has only wlc handler, no wl * they both check up, not only because there is no need to off/restore d11 interrupt * but also because per-port code may require sync with valid interrupt. */ static u32 wlc_wlintrsoff(struct wlc_info *wlc) { if (!wlc->hw->up) return 0; return wl_intrsoff(wlc->wl); } static void wlc_wlintrsrestore(struct wlc_info *wlc, u32 macintmask) { if (!wlc->hw->up) return; wl_intrsrestore(wlc->wl, macintmask); } u32 wlc_intrsoff(struct wlc_info *wlc) { struct wlc_hw_info *wlc_hw = wlc->hw; u32 macintmask; if (!wlc_hw->clk) return 0; macintmask = wlc->macintmask; /* isr can still happen */ W_REG(&wlc_hw->regs->macintmask, 0); (void)R_REG(&wlc_hw->regs->macintmask); /* sync readback */ udelay(1); /* ensure int line is no longer driven */ wlc->macintmask = 0; /* return previous macintmask; resolve race between us and our isr */ return wlc->macintstatus ? 0 : macintmask; } void wlc_intrsrestore(struct wlc_info *wlc, u32 macintmask) { struct wlc_hw_info *wlc_hw = wlc->hw; if (!wlc_hw->clk) return; wlc->macintmask = macintmask; W_REG(&wlc_hw->regs->macintmask, wlc->macintmask); } static void wlc_bmac_mute(struct wlc_hw_info *wlc_hw, bool on, mbool flags) { u8 null_ether_addr[ETH_ALEN] = {0, 0, 0, 0, 0, 0}; if (on) { /* suspend tx fifos */ wlc_bmac_tx_fifo_suspend(wlc_hw, TX_DATA_FIFO); wlc_bmac_tx_fifo_suspend(wlc_hw, TX_CTL_FIFO); wlc_bmac_tx_fifo_suspend(wlc_hw, TX_AC_BK_FIFO); wlc_bmac_tx_fifo_suspend(wlc_hw, TX_AC_VI_FIFO); /* zero the address match register so we do not send ACKs */ wlc_bmac_set_addrmatch(wlc_hw, RCM_MAC_OFFSET, null_ether_addr); } else { /* resume tx fifos */ if (!wlc_hw->wlc->tx_suspended) { wlc_bmac_tx_fifo_resume(wlc_hw, TX_DATA_FIFO); } wlc_bmac_tx_fifo_resume(wlc_hw, TX_CTL_FIFO); wlc_bmac_tx_fifo_resume(wlc_hw, TX_AC_BK_FIFO); wlc_bmac_tx_fifo_resume(wlc_hw, TX_AC_VI_FIFO); /* Restore address */ wlc_bmac_set_addrmatch(wlc_hw, RCM_MAC_OFFSET, wlc_hw->etheraddr); } wlc_phy_mute_upd(wlc_hw->band->pi, on, flags); if (on) wlc_ucode_mute_override_set(wlc_hw); else wlc_ucode_mute_override_clear(wlc_hw); } int wlc_bmac_xmtfifo_sz_get(struct wlc_hw_info *wlc_hw, uint fifo, uint *blocks) { if (fifo >= NFIFO) return BCME_RANGE; *blocks = wlc_hw->xmtfifo_sz[fifo]; return 0; } /* wlc_bmac_tx_fifo_suspended: * Check the MAC's tx suspend status for a tx fifo. * * When the MAC acknowledges a tx suspend, it indicates that no more * packets will be transmitted out the radio. This is independent of * DMA channel suspension---the DMA may have finished suspending, or may still * be pulling data into a tx fifo, by the time the MAC acks the suspend * request. */ static bool wlc_bmac_tx_fifo_suspended(struct wlc_hw_info *wlc_hw, uint tx_fifo) { /* check that a suspend has been requested and is no longer pending */ /* * for DMA mode, the suspend request is set in xmtcontrol of the DMA engine, * and the tx fifo suspend at the lower end of the MAC is acknowledged in the * chnstatus register. * The tx fifo suspend completion is independent of the DMA suspend completion and * may be acked before or after the DMA is suspended. */ if (dma_txsuspended(wlc_hw->di[tx_fifo]) && (R_REG(&wlc_hw->regs->chnstatus) & (1 << tx_fifo)) == 0) return true; return false; } static void wlc_bmac_tx_fifo_suspend(struct wlc_hw_info *wlc_hw, uint tx_fifo) { u8 fifo = 1 << tx_fifo; /* Two clients of this code, 11h Quiet period and scanning. */ /* only suspend if not already suspended */ if ((wlc_hw->suspended_fifos & fifo) == fifo) return; /* force the core awake only if not already */ if (wlc_hw->suspended_fifos == 0) wlc_ucode_wake_override_set(wlc_hw, WLC_WAKE_OVERRIDE_TXFIFO); wlc_hw->suspended_fifos |= fifo; if (wlc_hw->di[tx_fifo]) { /* Suspending AMPDU transmissions in the middle can cause underflow * which may result in mismatch between ucode and driver * so suspend the mac before suspending the FIFO */ if (WLC_PHY_11N_CAP(wlc_hw->band)) wlc_suspend_mac_and_wait(wlc_hw->wlc); dma_txsuspend(wlc_hw->di[tx_fifo]); if (WLC_PHY_11N_CAP(wlc_hw->band)) wlc_enable_mac(wlc_hw->wlc); } } static void wlc_bmac_tx_fifo_resume(struct wlc_hw_info *wlc_hw, uint tx_fifo) { /* BMAC_NOTE: WLC_TX_FIFO_ENAB is done in wlc_dpc() for DMA case but need to be done * here for PIO otherwise the watchdog will catch the inconsistency and fire */ /* Two clients of this code, 11h Quiet period and scanning. */ if (wlc_hw->di[tx_fifo]) dma_txresume(wlc_hw->di[tx_fifo]); /* allow core to sleep again */ if (wlc_hw->suspended_fifos == 0) return; else { wlc_hw->suspended_fifos &= ~(1 << tx_fifo); if (wlc_hw->suspended_fifos == 0) wlc_ucode_wake_override_clear(wlc_hw, WLC_WAKE_OVERRIDE_TXFIFO); } } /* * Read and clear macintmask and macintstatus and intstatus registers. * This routine should be called with interrupts off * Return: * -1 if DEVICEREMOVED(wlc) evaluates to true; * 0 if the interrupt is not for us, or we are in some special cases; * device interrupt status bits otherwise. */ static inline u32 wlc_intstatus(struct wlc_info *wlc, bool in_isr) { struct wlc_hw_info *wlc_hw = wlc->hw; d11regs_t *regs = wlc_hw->regs; u32 macintstatus; /* macintstatus includes a DMA interrupt summary bit */ macintstatus = R_REG(®s->macintstatus); WL_TRACE("wl%d: macintstatus: 0x%x\n", wlc_hw->unit, macintstatus); /* detect cardbus removed, in power down(suspend) and in reset */ if (DEVICEREMOVED(wlc)) return -1; /* DEVICEREMOVED succeeds even when the core is still resetting, * handle that case here. */ if (macintstatus == 0xffffffff) return 0; /* defer unsolicited interrupts */ macintstatus &= (in_isr ? wlc->macintmask : wlc->defmacintmask); /* if not for us */ if (macintstatus == 0) return 0; /* interrupts are already turned off for CFE build * Caution: For CFE Turning off the interrupts again has some undesired * consequences */ /* turn off the interrupts */ W_REG(®s->macintmask, 0); (void)R_REG(®s->macintmask); /* sync readback */ wlc->macintmask = 0; /* clear device interrupts */ W_REG(®s->macintstatus, macintstatus); /* MI_DMAINT is indication of non-zero intstatus */ if (macintstatus & MI_DMAINT) { /* * only fifo interrupt enabled is I_RI in * RX_FIFO. If MI_DMAINT is set, assume it * is set and clear the interrupt. */ W_REG(®s->intctrlregs[RX_FIFO].intstatus, DEF_RXINTMASK); } return macintstatus; } /* Update wlc->macintstatus and wlc->intstatus[]. */ /* Return true if they are updated successfully. false otherwise */ bool wlc_intrsupd(struct wlc_info *wlc) { u32 macintstatus; ASSERT(wlc->macintstatus != 0); /* read and clear macintstatus and intstatus registers */ macintstatus = wlc_intstatus(wlc, false); /* device is removed */ if (macintstatus == 0xffffffff) return false; /* update interrupt status in software */ wlc->macintstatus |= macintstatus; return true; } /* * First-level interrupt processing. * Return true if this was our interrupt, false otherwise. * *wantdpc will be set to true if further wlc_dpc() processing is required, * false otherwise. */ bool BCMFASTPATH wlc_isr(struct wlc_info *wlc, bool *wantdpc) { struct wlc_hw_info *wlc_hw = wlc->hw; u32 macintstatus; *wantdpc = false; if (!wlc_hw->up || !wlc->macintmask) return false; /* read and clear macintstatus and intstatus registers */ macintstatus = wlc_intstatus(wlc, true); if (macintstatus == 0xffffffff) WL_ERROR("DEVICEREMOVED detected in the ISR code path\n"); /* it is not for us */ if (macintstatus == 0) return false; *wantdpc = true; /* save interrupt status bits */ ASSERT(wlc->macintstatus == 0); wlc->macintstatus = macintstatus; return true; } static bool BCMFASTPATH wlc_bmac_dotxstatus(struct wlc_hw_info *wlc_hw, tx_status_t *txs, u32 s2) { /* discard intermediate indications for ucode with one legitimate case: * e.g. if "useRTS" is set. ucode did a successful rts/cts exchange, but the subsequent * tx of DATA failed. so it will start rts/cts from the beginning (resetting the rts * transmission count) */ if (!(txs->status & TX_STATUS_AMPDU) && (txs->status & TX_STATUS_INTERMEDIATE)) { return false; } return wlc_dotxstatus(wlc_hw->wlc, txs, s2); } /* process tx completion events in BMAC * Return true if more tx status need to be processed. false otherwise. */ static bool BCMFASTPATH wlc_bmac_txstatus(struct wlc_hw_info *wlc_hw, bool bound, bool *fatal) { bool morepending = false; struct wlc_info *wlc = wlc_hw->wlc; d11regs_t *regs; tx_status_t txstatus, *txs; u32 s1, s2; uint n = 0; /* * Param 'max_tx_num' indicates max. # tx status to process before * break out. */ uint max_tx_num = bound ? wlc->pub->tunables->txsbnd : -1; WL_TRACE("wl%d: wlc_bmac_txstatus\n", wlc_hw->unit); txs = &txstatus; regs = wlc_hw->regs; while (!(*fatal) && (s1 = R_REG(®s->frmtxstatus)) & TXS_V) { if (s1 == 0xffffffff) { WL_ERROR("wl%d: %s: dead chip\n", wlc_hw->unit, __func__); ASSERT(s1 != 0xffffffff); return morepending; } s2 = R_REG(®s->frmtxstatus2); txs->status = s1 & TXS_STATUS_MASK; txs->frameid = (s1 & TXS_FID_MASK) >> TXS_FID_SHIFT; txs->sequence = s2 & TXS_SEQ_MASK; txs->phyerr = (s2 & TXS_PTX_MASK) >> TXS_PTX_SHIFT; txs->lasttxtime = 0; *fatal = wlc_bmac_dotxstatus(wlc_hw, txs, s2); /* !give others some time to run! */ if (++n >= max_tx_num) break; } if (*fatal) return 0; if (n >= max_tx_num) morepending = true; if (!pktq_empty(&wlc->active_queue->q)) wlc_send_q(wlc, wlc->active_queue); return morepending; } void wlc_suspend_mac_and_wait(struct wlc_info *wlc) { struct wlc_hw_info *wlc_hw = wlc->hw; d11regs_t *regs = wlc_hw->regs; u32 mc, mi; WL_TRACE("wl%d: wlc_suspend_mac_and_wait: bandunit %d\n", wlc_hw->unit, wlc_hw->band->bandunit); /* * Track overlapping suspend requests */ wlc_hw->mac_suspend_depth++; if (wlc_hw->mac_suspend_depth > 1) return; /* force the core awake */ wlc_ucode_wake_override_set(wlc_hw, WLC_WAKE_OVERRIDE_MACSUSPEND); mc = R_REG(®s->maccontrol); if (mc == 0xffffffff) { WL_ERROR("wl%d: %s: dead chip\n", wlc_hw->unit, __func__); wl_down(wlc->wl); return; } ASSERT(!(mc & MCTL_PSM_JMP_0)); ASSERT(mc & MCTL_PSM_RUN); ASSERT(mc & MCTL_EN_MAC); mi = R_REG(®s->macintstatus); if (mi == 0xffffffff) { WL_ERROR("wl%d: %s: dead chip\n", wlc_hw->unit, __func__); wl_down(wlc->wl); return; } ASSERT(!(mi & MI_MACSSPNDD)); wlc_bmac_mctrl(wlc_hw, MCTL_EN_MAC, 0); SPINWAIT(!(R_REG(®s->macintstatus) & MI_MACSSPNDD), WLC_MAX_MAC_SUSPEND); if (!(R_REG(®s->macintstatus) & MI_MACSSPNDD)) { WL_ERROR("wl%d: wlc_suspend_mac_and_wait: waited %d uS and MI_MACSSPNDD is still not on.\n", wlc_hw->unit, WLC_MAX_MAC_SUSPEND); WL_ERROR("wl%d: psmdebug 0x%08x, phydebug 0x%08x, psm_brc 0x%04x\n", wlc_hw->unit, R_REG(®s->psmdebug), R_REG(®s->phydebug), R_REG(®s->psm_brc)); } mc = R_REG(®s->maccontrol); if (mc == 0xffffffff) { WL_ERROR("wl%d: %s: dead chip\n", wlc_hw->unit, __func__); wl_down(wlc->wl); return; } ASSERT(!(mc & MCTL_PSM_JMP_0)); ASSERT(mc & MCTL_PSM_RUN); ASSERT(!(mc & MCTL_EN_MAC)); } void wlc_enable_mac(struct wlc_info *wlc) { struct wlc_hw_info *wlc_hw = wlc->hw; d11regs_t *regs = wlc_hw->regs; u32 mc, mi; WL_TRACE("wl%d: wlc_enable_mac: bandunit %d\n", wlc_hw->unit, wlc->band->bandunit); /* * Track overlapping suspend requests */ ASSERT(wlc_hw->mac_suspend_depth > 0); wlc_hw->mac_suspend_depth--; if (wlc_hw->mac_suspend_depth > 0) return; mc = R_REG(®s->maccontrol); ASSERT(!(mc & MCTL_PSM_JMP_0)); ASSERT(!(mc & MCTL_EN_MAC)); ASSERT(mc & MCTL_PSM_RUN); wlc_bmac_mctrl(wlc_hw, MCTL_EN_MAC, MCTL_EN_MAC); W_REG(®s->macintstatus, MI_MACSSPNDD); mc = R_REG(®s->maccontrol); ASSERT(!(mc & MCTL_PSM_JMP_0)); ASSERT(mc & MCTL_EN_MAC); ASSERT(mc & MCTL_PSM_RUN); mi = R_REG(®s->macintstatus); ASSERT(!(mi & MI_MACSSPNDD)); wlc_ucode_wake_override_clear(wlc_hw, WLC_WAKE_OVERRIDE_MACSUSPEND); } static void wlc_upd_ofdm_pctl1_table(struct wlc_hw_info *wlc_hw) { u8 rate; u8 rates[8] = { WLC_RATE_6M, WLC_RATE_9M, WLC_RATE_12M, WLC_RATE_18M, WLC_RATE_24M, WLC_RATE_36M, WLC_RATE_48M, WLC_RATE_54M }; u16 entry_ptr; u16 pctl1; uint i; if (!WLC_PHY_11N_CAP(wlc_hw->band)) return; /* walk the phy rate table and update the entries */ for (i = 0; i < ARRAY_SIZE(rates); i++) { rate = rates[i]; entry_ptr = wlc_bmac_ofdm_ratetable_offset(wlc_hw, rate); /* read the SHM Rate Table entry OFDM PCTL1 values */ pctl1 = wlc_bmac_read_shm(wlc_hw, entry_ptr + M_RT_OFDM_PCTL1_POS); /* modify the value */ pctl1 &= ~PHY_TXC1_MODE_MASK; pctl1 |= (wlc_hw->hw_stf_ss_opmode << PHY_TXC1_MODE_SHIFT); /* Update the SHM Rate Table entry OFDM PCTL1 values */ wlc_bmac_write_shm(wlc_hw, entry_ptr + M_RT_OFDM_PCTL1_POS, pctl1); } } static u16 wlc_bmac_ofdm_ratetable_offset(struct wlc_hw_info *wlc_hw, u8 rate) { uint i; u8 plcp_rate = 0; struct plcp_signal_rate_lookup { u8 rate; u8 signal_rate; }; /* OFDM RATE sub-field of PLCP SIGNAL field, per 802.11 sec 17.3.4.1 */ const struct plcp_signal_rate_lookup rate_lookup[] = { {WLC_RATE_6M, 0xB}, {WLC_RATE_9M, 0xF}, {WLC_RATE_12M, 0xA}, {WLC_RATE_18M, 0xE}, {WLC_RATE_24M, 0x9}, {WLC_RATE_36M, 0xD}, {WLC_RATE_48M, 0x8}, {WLC_RATE_54M, 0xC} }; for (i = 0; i < ARRAY_SIZE(rate_lookup); i++) { if (rate == rate_lookup[i].rate) { plcp_rate = rate_lookup[i].signal_rate; break; } } /* Find the SHM pointer to the rate table entry by looking in the * Direct-map Table */ return 2 * wlc_bmac_read_shm(wlc_hw, M_RT_DIRMAP_A + (plcp_rate * 2)); } void wlc_bmac_band_stf_ss_set(struct wlc_hw_info *wlc_hw, u8 stf_mode) { wlc_hw->hw_stf_ss_opmode = stf_mode; if (wlc_hw->clk) wlc_upd_ofdm_pctl1_table(wlc_hw); } void BCMFASTPATH wlc_bmac_read_tsf(struct wlc_hw_info *wlc_hw, u32 *tsf_l_ptr, u32 *tsf_h_ptr) { d11regs_t *regs = wlc_hw->regs; /* read the tsf timer low, then high to get an atomic read */ *tsf_l_ptr = R_REG(®s->tsf_timerlow); *tsf_h_ptr = R_REG(®s->tsf_timerhigh); return; } static bool wlc_bmac_validate_chip_access(struct wlc_hw_info *wlc_hw) { d11regs_t *regs; u32 w, val; WL_TRACE("wl%d: validate_chip_access\n", wlc_hw->unit); regs = wlc_hw->regs; /* Validate dchip register access */ W_REG(®s->objaddr, OBJADDR_SHM_SEL | 0); (void)R_REG(®s->objaddr); w = R_REG(®s->objdata); /* Can we write and read back a 32bit register? */ W_REG(®s->objaddr, OBJADDR_SHM_SEL | 0); (void)R_REG(®s->objaddr); W_REG(®s->objdata, (u32) 0xaa5555aa); W_REG(®s->objaddr, OBJADDR_SHM_SEL | 0); (void)R_REG(®s->objaddr); val = R_REG(®s->objdata); if (val != (u32) 0xaa5555aa) { WL_ERROR("wl%d: validate_chip_access: SHM = 0x%x, expected 0xaa5555aa\n", wlc_hw->unit, val); return false; } W_REG(®s->objaddr, OBJADDR_SHM_SEL | 0); (void)R_REG(®s->objaddr); W_REG(®s->objdata, (u32) 0x55aaaa55); W_REG(®s->objaddr, OBJADDR_SHM_SEL | 0); (void)R_REG(®s->objaddr); val = R_REG(®s->objdata); if (val != (u32) 0x55aaaa55) { WL_ERROR("wl%d: validate_chip_access: SHM = 0x%x, expected 0x55aaaa55\n", wlc_hw->unit, val); return false; } W_REG(®s->objaddr, OBJADDR_SHM_SEL | 0); (void)R_REG(®s->objaddr); W_REG(®s->objdata, w); /* clear CFPStart */ W_REG(®s->tsf_cfpstart, 0); w = R_REG(®s->maccontrol); if ((w != (MCTL_IHR_EN | MCTL_WAKE)) && (w != (MCTL_IHR_EN | MCTL_GMODE | MCTL_WAKE))) { WL_ERROR("wl%d: validate_chip_access: maccontrol = 0x%x, expected 0x%x or 0x%x\n", wlc_hw->unit, w, (MCTL_IHR_EN | MCTL_WAKE), (MCTL_IHR_EN | MCTL_GMODE | MCTL_WAKE)); return false; } return true; } #define PHYPLL_WAIT_US 100000 void wlc_bmac_core_phypll_ctl(struct wlc_hw_info *wlc_hw, bool on) { d11regs_t *regs; u32 tmp; WL_TRACE("wl%d: wlc_bmac_core_phypll_ctl\n", wlc_hw->unit); tmp = 0; regs = wlc_hw->regs; if (on) { if ((wlc_hw->sih->chip == BCM4313_CHIP_ID)) { OR_REG(®s->clk_ctl_st, (CCS_ERSRC_REQ_HT | CCS_ERSRC_REQ_D11PLL | CCS_ERSRC_REQ_PHYPLL)); SPINWAIT((R_REG(®s->clk_ctl_st) & (CCS_ERSRC_AVAIL_HT)) != (CCS_ERSRC_AVAIL_HT), PHYPLL_WAIT_US); tmp = R_REG(®s->clk_ctl_st); if ((tmp & (CCS_ERSRC_AVAIL_HT)) != (CCS_ERSRC_AVAIL_HT)) { WL_ERROR("%s: turn on PHY PLL failed\n", __func__); ASSERT(0); } } else { OR_REG(®s->clk_ctl_st, (CCS_ERSRC_REQ_D11PLL | CCS_ERSRC_REQ_PHYPLL)); SPINWAIT((R_REG(®s->clk_ctl_st) & (CCS_ERSRC_AVAIL_D11PLL | CCS_ERSRC_AVAIL_PHYPLL)) != (CCS_ERSRC_AVAIL_D11PLL | CCS_ERSRC_AVAIL_PHYPLL), PHYPLL_WAIT_US); tmp = R_REG(®s->clk_ctl_st); if ((tmp & (CCS_ERSRC_AVAIL_D11PLL | CCS_ERSRC_AVAIL_PHYPLL)) != (CCS_ERSRC_AVAIL_D11PLL | CCS_ERSRC_AVAIL_PHYPLL)) { WL_ERROR("%s: turn on PHY PLL failed\n", __func__); ASSERT(0); } } } else { /* Since the PLL may be shared, other cores can still be requesting it; * so we'll deassert the request but not wait for status to comply. */ AND_REG(®s->clk_ctl_st, ~CCS_ERSRC_REQ_PHYPLL); tmp = R_REG(®s->clk_ctl_st); } } void wlc_coredisable(struct wlc_hw_info *wlc_hw) { bool dev_gone; WL_TRACE("wl%d: %s\n", wlc_hw->unit, __func__); ASSERT(!wlc_hw->up); dev_gone = DEVICEREMOVED(wlc_hw->wlc); if (dev_gone) return; if (wlc_hw->noreset) return; /* radio off */ wlc_phy_switch_radio(wlc_hw->band->pi, OFF); /* turn off analog core */ wlc_phy_anacore(wlc_hw->band->pi, OFF); /* turn off PHYPLL to save power */ wlc_bmac_core_phypll_ctl(wlc_hw, false); /* No need to set wlc->pub->radio_active = OFF * because this function needs down capability and * radio_active is designed for BCMNODOWN. */ /* remove gpio controls */ if (wlc_hw->ucode_dbgsel) si_gpiocontrol(wlc_hw->sih, ~0, 0, GPIO_DRV_PRIORITY); wlc_hw->clk = false; si_core_disable(wlc_hw->sih, 0); wlc_phy_hw_clk_state_upd(wlc_hw->band->pi, false); } /* power both the pll and external oscillator on/off */ static void wlc_bmac_xtal(struct wlc_hw_info *wlc_hw, bool want) { WL_TRACE("wl%d: wlc_bmac_xtal: want %d\n", wlc_hw->unit, want); /* dont power down if plldown is false or we must poll hw radio disable */ if (!want && wlc_hw->pllreq) return; if (wlc_hw->sih) si_clkctl_xtal(wlc_hw->sih, XTAL | PLL, want); wlc_hw->sbclk = want; if (!wlc_hw->sbclk) { wlc_hw->clk = false; if (wlc_hw->band && wlc_hw->band->pi) wlc_phy_hw_clk_state_upd(wlc_hw->band->pi, false); } } static void wlc_flushqueues(struct wlc_info *wlc) { struct wlc_hw_info *wlc_hw = wlc->hw; uint i; wlc->txpend16165war = 0; /* free any posted tx packets */ for (i = 0; i < NFIFO; i++) if (wlc_hw->di[i]) { dma_txreclaim(wlc_hw->di[i], HNDDMA_RANGE_ALL); TXPKTPENDCLR(wlc, i); WL_TRACE("wlc_flushqueues: pktpend fifo %d cleared\n", i); } /* free any posted rx packets */ dma_rxreclaim(wlc_hw->di[RX_FIFO]); } u16 wlc_bmac_read_shm(struct wlc_hw_info *wlc_hw, uint offset) { return wlc_bmac_read_objmem(wlc_hw, offset, OBJADDR_SHM_SEL); } void wlc_bmac_write_shm(struct wlc_hw_info *wlc_hw, uint offset, u16 v) { wlc_bmac_write_objmem(wlc_hw, offset, v, OBJADDR_SHM_SEL); } /* Set a range of shared memory to a value. * SHM 'offset' needs to be an even address and * Buffer length 'len' must be an even number of bytes */ void wlc_bmac_set_shm(struct wlc_hw_info *wlc_hw, uint offset, u16 v, int len) { int i; /* offset and len need to be even */ ASSERT((offset & 1) == 0); ASSERT((len & 1) == 0); if (len <= 0) return; for (i = 0; i < len; i += 2) { wlc_bmac_write_objmem(wlc_hw, offset + i, v, OBJADDR_SHM_SEL); } } static u16 wlc_bmac_read_objmem(struct wlc_hw_info *wlc_hw, uint offset, u32 sel) { d11regs_t *regs = wlc_hw->regs; volatile u16 *objdata_lo = (volatile u16 *)®s->objdata; volatile u16 *objdata_hi = objdata_lo + 1; u16 v; ASSERT((offset & 1) == 0); W_REG(®s->objaddr, sel | (offset >> 2)); (void)R_REG(®s->objaddr); if (offset & 2) { v = R_REG(objdata_hi); } else { v = R_REG(objdata_lo); } return v; } static void wlc_bmac_write_objmem(struct wlc_hw_info *wlc_hw, uint offset, u16 v, u32 sel) { d11regs_t *regs = wlc_hw->regs; volatile u16 *objdata_lo = (volatile u16 *)®s->objdata; volatile u16 *objdata_hi = objdata_lo + 1; ASSERT((offset & 1) == 0); W_REG(®s->objaddr, sel | (offset >> 2)); (void)R_REG(®s->objaddr); if (offset & 2) { W_REG(objdata_hi, v); } else { W_REG(objdata_lo, v); } } /* Copy a buffer to shared memory of specified type . * SHM 'offset' needs to be an even address and * Buffer length 'len' must be an even number of bytes * 'sel' selects the type of memory */ void wlc_bmac_copyto_objmem(struct wlc_hw_info *wlc_hw, uint offset, const void *buf, int len, u32 sel) { u16 v; const u8 *p = (const u8 *)buf; int i; /* offset and len need to be even */ ASSERT((offset & 1) == 0); ASSERT((len & 1) == 0); if (len <= 0) return; for (i = 0; i < len; i += 2) { v = p[i] | (p[i + 1] << 8); wlc_bmac_write_objmem(wlc_hw, offset + i, v, sel); } } /* Copy a piece of shared memory of specified type to a buffer . * SHM 'offset' needs to be an even address and * Buffer length 'len' must be an even number of bytes * 'sel' selects the type of memory */ void wlc_bmac_copyfrom_objmem(struct wlc_hw_info *wlc_hw, uint offset, void *buf, int len, u32 sel) { u16 v; u8 *p = (u8 *) buf; int i; /* offset and len need to be even */ ASSERT((offset & 1) == 0); ASSERT((len & 1) == 0); if (len <= 0) return; for (i = 0; i < len; i += 2) { v = wlc_bmac_read_objmem(wlc_hw, offset + i, sel); p[i] = v & 0xFF; p[i + 1] = (v >> 8) & 0xFF; } } void wlc_bmac_copyfrom_vars(struct wlc_hw_info *wlc_hw, char **buf, uint *len) { WL_TRACE("wlc_bmac_copyfrom_vars, nvram vars totlen=%d\n", wlc_hw->vars_size); *buf = wlc_hw->vars; *len = wlc_hw->vars_size; } void wlc_bmac_retrylimit_upd(struct wlc_hw_info *wlc_hw, u16 SRL, u16 LRL) { wlc_hw->SRL = SRL; wlc_hw->LRL = LRL; /* write retry limit to SCR, shouldn't need to suspend */ if (wlc_hw->up) { W_REG(&wlc_hw->regs->objaddr, OBJADDR_SCR_SEL | S_DOT11_SRC_LMT); (void)R_REG(&wlc_hw->regs->objaddr); W_REG(&wlc_hw->regs->objdata, wlc_hw->SRL); W_REG(&wlc_hw->regs->objaddr, OBJADDR_SCR_SEL | S_DOT11_LRC_LMT); (void)R_REG(&wlc_hw->regs->objaddr); W_REG(&wlc_hw->regs->objdata, wlc_hw->LRL); } } void wlc_bmac_set_noreset(struct wlc_hw_info *wlc_hw, bool noreset_flag) { wlc_hw->noreset = noreset_flag; } void wlc_bmac_pllreq(struct wlc_hw_info *wlc_hw, bool set, mbool req_bit) { ASSERT(req_bit); if (set) { if (mboolisset(wlc_hw->pllreq, req_bit)) return; mboolset(wlc_hw->pllreq, req_bit); if (mboolisset(wlc_hw->pllreq, WLC_PLLREQ_FLIP)) { if (!wlc_hw->sbclk) { wlc_bmac_xtal(wlc_hw, ON); } } } else { if (!mboolisset(wlc_hw->pllreq, req_bit)) return; mboolclr(wlc_hw->pllreq, req_bit); if (mboolisset(wlc_hw->pllreq, WLC_PLLREQ_FLIP)) { if (wlc_hw->sbclk) { wlc_bmac_xtal(wlc_hw, OFF); } } } return; } /* this will be true for all ai chips */ bool wlc_bmac_taclear(struct wlc_hw_info *wlc_hw, bool ta_ok) { return true; } u16 wlc_bmac_rate_shm_offset(struct wlc_hw_info *wlc_hw, u8 rate) { u16 table_ptr; u8 phy_rate, index; /* get the phy specific rate encoding for the PLCP SIGNAL field */ /* XXX4321 fixup needed ? */ if (IS_OFDM(rate)) table_ptr = M_RT_DIRMAP_A; else table_ptr = M_RT_DIRMAP_B; /* for a given rate, the LS-nibble of the PLCP SIGNAL field is * the index into the rate table. */ phy_rate = rate_info[rate] & RATE_MASK; index = phy_rate & 0xf; /* Find the SHM pointer to the rate table entry by looking in the * Direct-map Table */ return 2 * wlc_bmac_read_shm(wlc_hw, table_ptr + (index * 2)); } void wlc_bmac_antsel_set(struct wlc_hw_info *wlc_hw, u32 antsel_avail) { wlc_hw->antsel_avail = antsel_avail; }