/* $OpenBSD: if_san_xilinx.c,v 1.32 2014/12/05 15:50:04 mpi Exp $ */ /*- * Copyright (c) 2001-2004 Sangoma Technologies (SAN) * All rights reserved. www.sangoma.com * * This code is written by Nenad Corbic and * Alex Feldman for SAN. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above * copyright notice, this list of conditions and the following disclaimer * in the documentation and/or other materials provided with the * distribution. * 3. Neither the name of Sangoma Technologies nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY SANGOMA TECHNOLOGIES AND CONTRIBUTORS * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF * THE POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* Private critical flags */ enum { POLL_CRIT = PRIV_CRIT, TX_BUSY, RX_BUSY, TASK_POLL, CARD_DOWN }; enum { LINK_DOWN, DEVICE_DOWN }; #define MAX_IP_ERRORS 10 #define PORT(x) (x == 0 ? "PRIMARY" : "SECONDARY" ) #define MAX_TX_BUF 10 #define MAX_RX_BUF 10 #undef DEB_XILINX #if 1 # define TRUE_FIFO_SIZE 1 #else # undef TRUE_FIFO_SIZE # define HARD_FIFO_CODE 0x01 #endif static int aft_rx_copyback = MHLEN; struct xilinx_rx_buffer { SIMPLEQ_ENTRY(xilinx_rx_buffer) entry; struct mbuf *mbuf; bus_dmamap_t dma_map; wp_rx_element_t rx_el; }; SIMPLEQ_HEAD(xilinx_rx_head, xilinx_rx_buffer); /* * This structure is placed in the private data area of the device structure. * The card structure used to occupy the private area but now the following * structure will incorporate the card structure along with Protocol specific * data */ typedef struct { wanpipe_common_t common; struct ifqueue wp_tx_pending_list; struct ifqueue wp_tx_complete_list; struct xilinx_rx_head wp_rx_free_list; struct xilinx_rx_head wp_rx_complete_list; struct xilinx_rx_buffer *wp_rx_buffers; struct xilinx_rx_buffer *wp_rx_buffer_last; struct xilinx_rx_buffer *rx_dma_buf; bus_dma_tag_t dmatag; bus_dmamap_t tx_dmamap; struct mbuf *tx_dma_mbuf; u_int8_t tx_dma_cnt; unsigned long time_slot_map; unsigned char num_of_time_slots; long logic_ch_num; unsigned char dma_status; unsigned char ignore_modem; struct ifqueue udp_queue; unsigned long router_start_time; unsigned long tick_counter; /* For 5s timeout counter */ unsigned long router_up_time; unsigned char mc; /* Mulitcast support on/off */ unsigned char udp_pkt_src; /* udp packet processing */ unsigned short timer_int_enabled; unsigned char interface_down; u_int8_t gateway; u_int8_t true_if_encoding; char if_name[IFNAMSIZ+1]; u_int8_t idle_flag; u_int16_t max_idle_size; u_int8_t idle_start; u_int8_t pkt_error; u_int8_t rx_fifo_err_cnt; int first_time_slot; unsigned long tx_dma_addr; unsigned int tx_dma_len; unsigned char rx_dma; unsigned char pci_retry; unsigned char fifo_size_code; unsigned char fifo_base_addr; unsigned char fifo_size; int dma_mtu; void *prot_ch; wan_trace_t trace_info; }xilinx_softc_t; #define WAN_IFP_TO_SOFTC(ifp) (xilinx_softc_t *)((ifp)->if_softc) /* Route Status options */ #define NO_ROUTE 0x00 #define ADD_ROUTE 0x01 #define ROUTE_ADDED 0x02 #define REMOVE_ROUTE 0x03 #define WP_WAIT 0 #define WP_NO_WAIT 1 /* variable for keeping track of enabling/disabling FT1 monitor status */ /* static int rCount; */ extern void disable_irq(unsigned int); extern void enable_irq(unsigned int); extern int ticks; /**SECTOIN************************************************** * * Function Prototypes * ***********************************************************/ /* WAN link driver entry points. These are called by the WAN router module. */ static int wan_xilinx_release(sdla_t*, struct ifnet *); /* Network device interface */ static int wan_xilinx_up(struct ifnet *); static int wan_xilinx_down(struct ifnet *); static int wan_xilinx_ioctl(struct ifnet *, u_long cmd, struct ifreq *); static int wan_xilinx_send(struct mbuf *, struct ifnet *); static void handle_front_end_state(void *); static void enable_timer(void *); /* Miscellaneous Functions */ static void port_set_state (sdla_t *, int); /* Interrupt handlers */ static void wp_xilinx_isr (sdla_t *); /* Miscellaneous functions */ static int process_udp_mgmt_pkt(sdla_t *, struct ifnet *, xilinx_softc_t *, int); /* Bottom half handlers */ static void xilinx_process_packet(xilinx_softc_t *); static int xilinx_chip_configure(sdla_t *); static int xilinx_chip_unconfigure(sdla_t *); static int xilinx_dev_configure(sdla_t *, xilinx_softc_t *); static void xilinx_dev_unconfigure(sdla_t *, xilinx_softc_t *); static int xilinx_dma_rx(sdla_t *, xilinx_softc_t *); static void xilinx_dev_enable(sdla_t *, xilinx_softc_t *); static void xilinx_dev_close(sdla_t *, xilinx_softc_t *); static int xilinx_dma_tx (sdla_t *, xilinx_softc_t *); static void xilinx_dma_tx_complete (sdla_t *, xilinx_softc_t *); static void xilinx_dma_rx_complete (sdla_t *, xilinx_softc_t *); static void xilinx_dma_max_logic_ch(sdla_t *); static int xilinx_init_rx_dev_fifo(sdla_t *, xilinx_softc_t *, unsigned char); static void xilinx_init_tx_dma_descr(sdla_t *, xilinx_softc_t *); static int xilinx_init_tx_dev_fifo(sdla_t *, xilinx_softc_t *, unsigned char); static void xilinx_tx_post_complete(sdla_t *, xilinx_softc_t *, struct mbuf *); static void xilinx_rx_post_complete(sdla_t *, xilinx_softc_t *, struct xilinx_rx_buffer *, struct mbuf **, u_char *); static char request_xilinx_logical_channel_num(sdla_t *, xilinx_softc_t *, long *); static void free_xilinx_logical_channel_num (sdla_t *, int); static unsigned char read_cpld(sdla_t *, unsigned short); static unsigned char write_cpld(sdla_t *, unsigned short, unsigned char); static void front_end_interrupt(sdla_t *, unsigned long); static void enable_data_error_intr(sdla_t *); static void disable_data_error_intr(sdla_t *, unsigned char); static void xilinx_tx_fifo_under_recover(sdla_t *, xilinx_softc_t *); static int xilinx_write_ctrl_hdlc(sdla_t *, u_int32_t, u_int8_t, u_int32_t); static int set_chan_state(sdla_t*, struct ifnet*, int); static int fifo_error_interrupt(sdla_t *, unsigned long); static int request_fifo_baddr_and_size(sdla_t *, xilinx_softc_t *); static int map_fifo_baddr_and_size(sdla_t *, unsigned char, unsigned char *); static int free_fifo_baddr_and_size(sdla_t *, xilinx_softc_t *); static void aft_red_led_ctrl(sdla_t *, int); static void aft_led_timer(void *); static int aft_core_ready(sdla_t *); static int aft_alloc_rx_buffers(xilinx_softc_t *); static void aft_release_rx_buffers(xilinx_softc_t *); static int aft_alloc_rx_dma_buff(xilinx_softc_t *, int); static void aft_reload_rx_dma_buff(xilinx_softc_t *, struct xilinx_rx_buffer *); static void aft_release_rx_dma_buff(xilinx_softc_t *, struct xilinx_rx_buffer *); /* TE1 Control registers */ static WRITE_FRONT_END_REG_T write_front_end_reg; static READ_FRONT_END_REG_T read_front_end_reg; static void wan_ifmedia_sts(struct ifnet *, struct ifmediareq *); static int wan_ifmedia_upd(struct ifnet *); static void xilinx_delay(int sec) { #if 0 unsigned long timeout = ticks; while ((ticks - timeout) < (sec * hz)) { schedule(); } #endif } void * wan_xilinx_init(sdla_t *card) { xilinx_softc_t *sc; struct ifnet *ifp; /* Verify configuration ID */ bit_clear((u_int8_t *)&card->critical, CARD_DOWN); card->u.xilinx.num_of_ch = 0; card->u.xilinx.mru_trans = 1500; card->u.xilinx.dma_per_ch = 10; /* TE1 Make special hardware initialization for T1/E1 board */ if (IS_TE1(&card->fe_te.te_cfg)) { card->write_front_end_reg = write_front_end_reg; card->read_front_end_reg = read_front_end_reg; card->te_enable_timer = enable_timer; card->te_link_state = handle_front_end_state; } else card->front_end_status = FE_CONNECTED; /* WARNING: After this point the init function * must return with 0. The following bind * functions will cause problems if structures * below are not initialized */ card->del_if = &wan_xilinx_release; card->iface_up = &wan_xilinx_up; card->iface_down = &wan_xilinx_down; card->iface_send = &wan_xilinx_send; card->iface_ioctl= &wan_xilinx_ioctl; write_cpld(card, LED_CONTROL_REG, 0x0E); sdla_getcfg(card->hw, SDLA_BASEADDR, &card->u.xilinx.bar); xilinx_delay(1); timeout_set(&card->u.xilinx.led_timer, aft_led_timer, (void *)card); /* allocate and initialize private data */ sc = malloc(sizeof(*sc), M_DEVBUF, M_NOWAIT | M_ZERO); if (sc == NULL) return (NULL); ifp = (struct ifnet *)&sc->common.ifp; ifp->if_softc = sc; sc->common.card = card; if (wanpipe_generic_register(card, ifp, card->devname)) { free(sc, M_DEVBUF, 0); return (NULL); } strlcpy(sc->if_name, ifp->if_xname, IFNAMSIZ); sc->first_time_slot = -1; sc->time_slot_map = 0; sdla_getcfg(card->hw, SDLA_DMATAG, &sc->dmatag); IFQ_SET_MAXLEN(&sc->wp_tx_pending_list, MAX_TX_BUF); IFQ_SET_MAXLEN(&sc->wp_tx_complete_list, MAX_TX_BUF); aft_alloc_rx_buffers(sc); xilinx_delay(1); ifmedia_init(&sc->common.ifm, 0, wan_ifmedia_upd, wan_ifmedia_sts); if (IS_TE1(&card->fe_te.te_cfg)) { ifmedia_add(&sc->common.ifm, IFM_TDM|IFM_TDM_T1, 0, NULL); ifmedia_add(&sc->common.ifm, IFM_TDM|IFM_TDM_T1_AMI, 0, NULL); ifmedia_add(&sc->common.ifm, IFM_TDM|IFM_TDM_E1, 0, NULL); ifmedia_add(&sc->common.ifm, IFM_TDM|IFM_TDM_E1_AMI, 0, NULL); ifmedia_add(&sc->common.ifm, IFM_TDM|IFM_TDM_T1|IFM_TDM_PPP, 0, NULL); ifmedia_add(&sc->common.ifm, IFM_TDM|IFM_TDM_T1_AMI|IFM_TDM_PPP, 0, NULL); ifmedia_add(&sc->common.ifm, IFM_TDM|IFM_TDM_E1|IFM_TDM_PPP, 0, NULL); ifmedia_add(&sc->common.ifm, IFM_TDM|IFM_TDM_E1_AMI|IFM_TDM_PPP, 0, NULL); ifmedia_set(&sc->common.ifm, IFM_TDM|IFM_TDM_T1); } else { /* Currently we not support ifmedia types for other * front end types. */ } return (sc); } static int wan_xilinx_release(sdla_t* card, struct ifnet* ifp) { xilinx_softc_t *sc = ifp->if_softc; IF_PURGE(&sc->wp_tx_pending_list); if (sc->tx_dma_addr && sc->tx_dma_len) { sc->tx_dma_addr = 0; sc->tx_dma_len = 0; } if (sc->tx_dma_mbuf) { log(LOG_INFO, "freeing tx dma mbuf\n"); bus_dmamap_unload(sc->dmatag, sc->tx_dmamap); m_freem(sc->tx_dma_mbuf); sc->tx_dma_mbuf = NULL; } #if 0 bus_dmamap_destroy(sc->dmatag, sc->tx_dmamap); #endif if (sc->rx_dma_buf) { SIMPLEQ_INSERT_TAIL(&sc->wp_rx_free_list, sc->rx_dma_buf, entry); sc->rx_dma_buf = NULL; } aft_release_rx_buffers(sc); wanpipe_generic_unregister(ifp); ifp->if_softc = NULL; free(sc, M_DEVBUF, 0); return (0); } static void wan_ifmedia_sts(struct ifnet *ifp, struct ifmediareq *ifmreq) { wanpipe_common_t *common = (wanpipe_common_t *)ifp->if_softc; struct ifmedia *ifm; WAN_ASSERT1(common == NULL); ifm = &common->ifm; ifmreq->ifm_active = ifm->ifm_cur->ifm_media; } static int wan_ifmedia_upd(struct ifnet *ifp) { wanpipe_common_t *common = (wanpipe_common_t *)ifp->if_softc; sdla_t *card; WAN_ASSERT(common == NULL); WAN_ASSERT(common->card == NULL); card = (sdla_t *)common->card; if (IS_TE1(&card->fe_te.te_cfg)) return (sdla_te_setcfg(ifp, &common->ifm)); return (EINVAL); } /* * KERNEL Device Entry Interfaces */ static int wan_xilinx_up(struct ifnet *ifp) { xilinx_softc_t *sc = ifp->if_softc; sdla_t *card = NULL; struct timeval tv; int err = 0; WAN_ASSERT(sc == NULL); WAN_ASSERT(sc->common.card == NULL); card = (sdla_t *)sc->common.card; if (card->state != WAN_DISCONNECTED) return (0); sc->time_slot_map = card->fe_te.te_cfg.active_ch; sc->dma_mtu = xilinx_valid_mtu(ifp->if_mtu+100); if (!sc->dma_mtu) { log(LOG_INFO, "%s:%s: Error invalid MTU %u\n", card->devname, sc->if_name, ifp->if_mtu); return (EINVAL); } #ifdef DEBUG_INIT log(LOG_INFO, "%s: Allocating %d dma mbuf len=%d\n", card->devname, card->u.xilinx.dma_per_ch, sc->dma_mtu); #endif if (aft_alloc_rx_dma_buff(sc, card->u.xilinx.dma_per_ch) == 0) return (ENOMEM); if (bus_dmamap_create(sc->dmatag, sc->dma_mtu, 1, sc->dma_mtu, 0, BUS_DMA_NOWAIT | BUS_DMA_ALLOCNOW, &sc->tx_dmamap)) { log(LOG_INFO, "%s: Failed to allocate tx dmamap\n", sc->if_name); return (ENOMEM); } err = xilinx_chip_configure(card); if (err) return (EINVAL); card->isr = &wp_xilinx_isr; err = xilinx_dev_configure(card, sc); if (err) { xilinx_chip_unconfigure(card); return (EINVAL); } xilinx_delay(1); /* Initialize the router start time. * Used by wanpipemon debugger to indicate * how long has the interface been up */ microtime(&tv); sc->router_start_time = tv.tv_sec; xilinx_init_tx_dma_descr(card, sc); xilinx_dev_enable(card, sc); sc->ignore_modem = 0x0F; bit_clear((u_int8_t *)&card->critical, CARD_DOWN); port_set_state(card, WAN_CONNECTING); return (err); } static int wan_xilinx_down(struct ifnet *ifp) { xilinx_softc_t *sc = ifp->if_softc; sdla_t *card = (sdla_t *)sc->common.card; struct xilinx_rx_buffer *buf; int s; if (card->state == WAN_DISCONNECTED) return (0); xilinx_dev_close(card, sc); /* Disable DMA ENGINE before we perform * core reset. Otherwise, we will receive * rx fifo errors on subsequent resetart. */ disable_data_error_intr(card, DEVICE_DOWN); bit_set((u_int8_t *)&card->critical, CARD_DOWN); timeout_del(&card->u.xilinx.led_timer); /* TE1 - Unconfiging, only on shutdown */ if (IS_TE1(&card->fe_te.te_cfg)) sdla_te_unconfig(card); s = splnet(); card->isr = NULL; if (sc->tx_dma_addr && sc->tx_dma_len) { sc->tx_dma_addr = 0; sc->tx_dma_len = 0; } if (sc->tx_dma_mbuf) { bus_dmamap_unload(sc->dmatag, sc->tx_dmamap); m_freem(sc->tx_dma_mbuf); sc->tx_dma_mbuf = NULL; } bus_dmamap_destroy(sc->dmatag, sc->tx_dmamap); /* If there is something left in rx_dma_buf, then move it to * rx_free_list. */ if (sc->rx_dma_buf) { aft_reload_rx_dma_buff(sc, sc->rx_dma_buf); sc->rx_dma_buf = NULL; } while ((buf = SIMPLEQ_FIRST(&sc->wp_rx_free_list)) != NULL) { SIMPLEQ_REMOVE_HEAD(&sc->wp_rx_free_list, entry); aft_release_rx_dma_buff(sc, buf); } while ((buf = SIMPLEQ_FIRST(&sc->wp_rx_complete_list)) != NULL) { SIMPLEQ_REMOVE_HEAD(&sc->wp_rx_complete_list, entry); aft_release_rx_dma_buff(sc, buf); } splx(s); DELAY(10); xilinx_dev_unconfigure(card, sc); xilinx_chip_unconfigure(card); port_set_state(card, WAN_DISCONNECTED); sc->ignore_modem = 0x00; return (0); } static int wan_xilinx_send(struct mbuf* m, struct ifnet* ifp) { xilinx_softc_t *sc = ifp->if_softc; sdla_t *card = (sdla_t *)sc->common.card; /* Mark interface as busy. The kernel will not * attempt to send any more packets until we clear * this condition */ if (m == NULL) /* This should never happen. Just a sanity check. */ return (EINVAL); if (card->state != WAN_CONNECTED) { /* * The card is still not ready to transmit... * drop this packet! */ m_freem(m); return (EINVAL); } else { if (IF_QFULL(&sc->wp_tx_pending_list)) { int err; #ifdef DEBUG_TX log(LOG_INFO, "%s: Tx pending queue FULL\n", ifp->if_xname); #endif /* * TX pending queue is full. Try to send packet * from tx_pending queue (first) */ err = xilinx_dma_tx(card, sc); if (!err && !IF_QFULL(&sc->wp_tx_pending_list)) /* * On success, we have place for the new * tx packet, try to send it now! */ goto wan_xilinx_dma_tx_try; /* * Tx pedning queue is full. I can't accept new * tx packet, drop this packet and set interface * queue to OACTIVE */ m_freem(m); ifp->if_flags |= IFF_OACTIVE; return (EBUSY); } else { wan_xilinx_dma_tx_try: IF_ENQUEUE(&sc->wp_tx_pending_list, m); xilinx_dma_tx(card, sc); } } return (0); } static int wan_xilinx_ioctl(struct ifnet *ifp, u_long cmd, struct ifreq *ifr) { xilinx_softc_t *sc = (xilinx_softc_t *)ifp->if_softc; struct mbuf *m; sdla_t *card; wan_udp_pkt_t *wan_udp_pkt; int err = 0; if (!sc) return (ENODEV); card = (sdla_t *)sc->common.card; switch (cmd) { case SIOC_WANPIPE_PIPEMON: if ((err = suser(curproc, 0)) != 0) break; if (IF_QFULL(&sc->udp_queue)) return (EBUSY); /* * For performance reasons test the critical * here before spin lock */ if (bit_test((u_int8_t *)&card->in_isr, 0)) return (EBUSY); m = wan_mbuf_alloc(sizeof(wan_udp_pkt_t)); if (m == NULL) return (ENOMEM); wan_udp_pkt = mtod(m, wan_udp_pkt_t *); if (copyin(ifr->ifr_data, &wan_udp_pkt->wan_udp_hdr, sizeof(wan_udp_hdr_t))) { m_freem(m); return (EFAULT); } IF_ENQUEUE(&sc->udp_queue, m); process_udp_mgmt_pkt(card, ifp, sc, 1); if (copyout(&wan_udp_pkt->wan_udp_hdr, ifr->ifr_data, sizeof(wan_udp_hdr_t))) { m_freem(m); return (EFAULT); } IF_DEQUEUE(&sc->udp_queue, m); m_freem(m); return (0); default: if (card->ioctl) err = card->ioctl(ifp, cmd, ifr); break; } return (err); } /* * Process all "wanpipemon" debugger commands. This function * performs all debugging tasks: * * Line Tracing * Line/Hardware Statistics * Protocol Statistics * * "wanpipemon" utility is a user-space program that * is used to debug the WANPIPE product. */ static int process_udp_mgmt_pkt(sdla_t* card, struct ifnet* ifp, xilinx_softc_t* sc, int local_dev ) { struct mbuf *m; unsigned short buffer_length; wan_udp_pkt_t *wan_udp_pkt; wan_trace_t *trace_info = NULL; struct timeval tv; IF_POLL(&sc->udp_queue, m); if (m == NULL) return (EINVAL); wan_udp_pkt = mtod(m, wan_udp_pkt_t *); trace_info=&sc->trace_info; { struct mbuf *m0; wan_udp_pkt->wan_udp_opp_flag = 0; switch (wan_udp_pkt->wan_udp_command) { case READ_CONFIGURATION: case READ_CODE_VERSION: wan_udp_pkt->wan_udp_return_code = 0; wan_udp_pkt->wan_udp_data_len = 0; break; case ENABLE_TRACING: wan_udp_pkt->wan_udp_return_code = WAN_CMD_OK; wan_udp_pkt->wan_udp_data_len = 0; if (!bit_test((u_int8_t *) &trace_info->tracing_enabled, 0)) { trace_info->trace_timeout = ticks; IF_PURGE(&trace_info->ifq); if (wan_udp_pkt->wan_udp_data[0] == 0) { bit_clear((u_int8_t *) &trace_info->tracing_enabled, 1); log(LOG_INFO, "%s: ADSL L3 " "trace enabled!\n", card->devname); } else if (wan_udp_pkt->wan_udp_data[0] == 1) { bit_clear((u_int8_t *) &trace_info->tracing_enabled, 2 ); bit_set((u_int8_t *) &trace_info->tracing_enabled, 1); log(LOG_INFO, "%s: ADSL L2 " "trace enabled!\n", card->devname); } else { bit_clear((u_int8_t *) &trace_info->tracing_enabled, 1); bit_set((u_int8_t *) &trace_info->tracing_enabled, 2); log(LOG_INFO, "%s: ADSL L1 " "trace enabled!\n", card->devname); } bit_set((u_int8_t *)& trace_info->tracing_enabled, 0); } else { log(LOG_INFO, "%s: Error: AFT " "trace running!\n", card->devname); wan_udp_pkt->wan_udp_return_code = 2; } break; case DISABLE_TRACING: wan_udp_pkt->wan_udp_return_code = WAN_CMD_OK; if (bit_test((u_int8_t *) &trace_info->tracing_enabled, 0)) { bit_clear((u_int8_t *) &trace_info->tracing_enabled, 0); bit_clear((u_int8_t *) &trace_info->tracing_enabled, 1); bit_clear((u_int8_t *) &trace_info->tracing_enabled, 2); IF_PURGE(&trace_info->ifq); log(LOG_INFO, "%s: Disabling ADSL trace\n", card->devname); } else { /* * set return code to line trace already * disabled */ wan_udp_pkt->wan_udp_return_code = 1; } break; case GET_TRACE_INFO: if (bit_test((u_int8_t *) &trace_info->tracing_enabled, 0)) { trace_info->trace_timeout = ticks; } else { log(LOG_INFO, "%s: Error AFT trace " "not enabled\n", card->devname); /* set return code */ wan_udp_pkt->wan_udp_return_code = 1; break; } buffer_length = 0; wan_udp_pkt->wan_udp_aft_num_frames = 0; wan_udp_pkt->wan_udp_aft_ismoredata = 0; while (!IF_IS_EMPTY(&trace_info->ifq)) { IF_POLL(&trace_info->ifq, m0); if (m0 == NULL) { log(LOG_INFO, "%s: No more " "trace packets in trace queue!\n", card->devname); break; } if ((WAN_MAX_DATA_SIZE - buffer_length) < m0->m_pkthdr.len) { /* * indicate there are more frames * on board & exit */ wan_udp_pkt->wan_udp_aft_ismoredata = 0x01; break; } m_copydata(m0, 0, m0->m_pkthdr.len, &wan_udp_pkt->wan_udp_data[buffer_length]); buffer_length += m0->m_pkthdr.len; IF_DEQUEUE(&trace_info->ifq, m0); if (m0) m_freem(m0); wan_udp_pkt->wan_udp_aft_num_frames++; } /* set the data length and return code */ wan_udp_pkt->wan_udp_data_len = buffer_length; wan_udp_pkt->wan_udp_return_code = WAN_CMD_OK; break; case ROUTER_UP_TIME: microtime(&tv); sc->router_up_time = tv.tv_sec; sc->router_up_time -= sc->router_start_time; *(unsigned long *)&wan_udp_pkt->wan_udp_data = sc->router_up_time; wan_udp_pkt->wan_udp_data_len = sizeof(unsigned long); wan_udp_pkt->wan_udp_return_code = 0; break; case WAN_GET_MEDIA_TYPE: case WAN_FE_GET_STAT: case WAN_FE_SET_LB_MODE: case WAN_FE_FLUSH_PMON: case WAN_FE_GET_CFG: if (IS_TE1(&card->fe_te.te_cfg)) { sdla_te_udp(card, &wan_udp_pkt->wan_udp_cmd, &wan_udp_pkt->wan_udp_data[0]); } else { if (wan_udp_pkt->wan_udp_command == WAN_GET_MEDIA_TYPE) { wan_udp_pkt->wan_udp_data_len = sizeof(unsigned char); wan_udp_pkt->wan_udp_return_code = WAN_CMD_OK; } else { wan_udp_pkt->wan_udp_return_code = WAN_UDP_INVALID_CMD; } } break; case WAN_GET_PROTOCOL: wan_udp_pkt->wan_udp_aft_num_frames = WANCONFIG_AFT; wan_udp_pkt->wan_udp_return_code = WAN_CMD_OK; wan_udp_pkt->wan_udp_data_len = 1; break; case WAN_GET_PLATFORM: wan_udp_pkt->wan_udp_data[0] = WAN_PLATFORM_ID; wan_udp_pkt->wan_udp_return_code = WAN_CMD_OK; wan_udp_pkt->wan_udp_data_len = 1; break; default: wan_udp_pkt->wan_udp_data_len = 0; wan_udp_pkt->wan_udp_return_code = 0xCD; log(LOG_INFO, "%s: Warning, Illegal UDP " "command attempted from network: %x\n", card->devname, wan_udp_pkt->wan_udp_command); break; } } wan_udp_pkt->wan_udp_request_reply = UDPMGMT_REPLY; return (1); } /* * FIRMWARE Specific Interface Functions */ static int xilinx_chip_configure(sdla_t *card) { u_int32_t reg, tmp; int err = 0; u_int16_t adapter_type, adptr_security; #ifdef DEBUG_INIT log(LOG_DEBUG, "Xilinx Chip Configuration. -- \n"); #endif xilinx_delay(1); sdla_bus_read_4(card->hw, XILINX_CHIP_CFG_REG, ®); /* Configure for T1 or E1 front end */ if (IS_T1(&card->fe_te.te_cfg)) { card->u.xilinx.num_of_time_slots = NUM_OF_T1_CHANNELS; bit_clear((u_int8_t *)®, INTERFACE_TYPE_T1_E1_BIT); bit_set((u_int8_t *)®, FRONT_END_FRAME_FLAG_ENABLE_BIT); } else if (IS_E1(&card->fe_te.te_cfg)) { card->u.xilinx.num_of_time_slots = NUM_OF_E1_CHANNELS; bit_set((u_int8_t *)®, INTERFACE_TYPE_T1_E1_BIT); bit_set((u_int8_t *)®, FRONT_END_FRAME_FLAG_ENABLE_BIT); } else { log(LOG_INFO, "%s: Error: Xilinx doesn't " "support non T1/E1 interface!\n", card->devname); return (EINVAL); } sdla_bus_write_4(card->hw, XILINX_CHIP_CFG_REG, reg); DELAY(10000); /* Reset PMC */ sdla_bus_read_4(card->hw, XILINX_CHIP_CFG_REG, ®); bit_clear((u_int8_t *)®, FRONT_END_RESET_BIT); sdla_bus_write_4(card->hw, XILINX_CHIP_CFG_REG, reg); DELAY(1000); bit_set((u_int8_t *)®, FRONT_END_RESET_BIT); sdla_bus_write_4(card->hw, XILINX_CHIP_CFG_REG, reg); DELAY(100); #ifdef DEBUG_INIT log(LOG_DEBUG, "--- Chip Reset. -- \n"); #endif /* Reset Chip Core */ sdla_bus_read_4(card->hw, XILINX_CHIP_CFG_REG, ®); bit_set((u_int8_t *)®, CHIP_RESET_BIT); sdla_bus_write_4(card->hw, XILINX_CHIP_CFG_REG, reg); DELAY(100); /* Disable the chip/hdlc reset condition */ bit_clear((u_int8_t *)®, CHIP_RESET_BIT); /* Disable ALL chip interrupts */ bit_clear((u_int8_t *)®, GLOBAL_INTR_ENABLE_BIT); bit_clear((u_int8_t *)®, ERROR_INTR_ENABLE_BIT); bit_clear((u_int8_t *)®, FRONT_END_INTR_ENABLE_BIT); sdla_bus_write_4(card->hw, XILINX_CHIP_CFG_REG, reg); xilinx_delay(1); sdla_getcfg(card->hw, SDLA_ADAPTERTYPE, &adapter_type); DELAY(100); #ifdef DEBUG_INIT log(LOG_INFO, "%s: Hardware Adapter Type 0x%X\n", card->devname, adapter_type); #endif adptr_security = read_cpld(card, SECURITY_CPLD_REG); adptr_security = adptr_security >> SECURITY_CPLD_SHIFT; adptr_security = adptr_security & SECURITY_CPLD_MASK; #ifdef DEBUG_INIT switch (adptr_security) { case SECURITY_1LINE_UNCH: log(LOG_INFO, "%s: Security 1 Line UnCh\n", card->devname); break; case SECURITY_1LINE_CH: log(LOG_INFO, "%s: Security 1 Line Ch\n", card->devname); break; case SECURITY_2LINE_UNCH: log(LOG_INFO, "%s: Security 2 Line UnCh\n", card->devname); break; case SECURITY_2LINE_CH: log(LOG_INFO, "%s: Security 2 Line Ch\n", card->devname); break; default: log(LOG_INFO, "%s: Error Invalid Security ID = 0x%X\n", card->devname, adptr_security); /* return EINVAL;*/ } #endif /* Turn off Onboard RED LED */ sdla_bus_read_4(card->hw, XILINX_CHIP_CFG_REG, ®); bit_set((u_int8_t *)®, XILINX_RED_LED); sdla_bus_write_4(card->hw, XILINX_CHIP_CFG_REG, reg); DELAY(10); err = aft_core_ready(card); if (err != 0) log(LOG_INFO, "%s: WARNING: HDLC Core Not Ready: B4 TE CFG!\n", card->devname); log(LOG_INFO, "%s: Configuring A101 PMC T1/E1/J1 Front End\n", card->devname); if (sdla_te_config(card)) { log(LOG_INFO, "%s: Failed %s configuration!\n", card->devname, IS_T1(&card->fe_te.te_cfg)?"T1":"E1"); return (EINVAL); } xilinx_delay(1); err = aft_core_ready(card); if (err != 0) { log(LOG_INFO, "%s: Error: HDLC Core Not Ready!\n", card->devname); sdla_bus_read_4(card->hw, XILINX_CHIP_CFG_REG, ®); /* Disable the chip/hdlc reset condition */ bit_set((u_int8_t *)®, CHIP_RESET_BIT); sdla_bus_write_4(card->hw, XILINX_CHIP_CFG_REG, reg); return (err); } #ifdef DEBUG_INIT log(LOG_INFO, "%s: HDLC Core Ready 0x%08X\n", card->devname, reg); #endif xilinx_delay(1); /* Setup global DMA parameters */ reg = 0; reg|=(XILINX_DMA_SIZE << DMA_SIZE_BIT_SHIFT); reg|=(XILINX_DMA_FIFO_UP << DMA_FIFO_HI_MARK_BIT_SHIFT); reg|=(XILINX_DMA_FIFO_LO << DMA_FIFO_LO_MARK_BIT_SHIFT); /* * Enable global DMA engine and set to default * number of active channels. Note: this value will * change in dev configuration */ reg|=(XILINX_DEFLT_ACTIVE_CH << DMA_ACTIVE_CHANNEL_BIT_SHIFT); bit_set((u_int8_t *)®, DMA_ENGINE_ENABLE_BIT); #ifdef DEBUG_INIT log(LOG_INFO, "--- Setup DMA control Reg. -- \n"); #endif sdla_bus_write_4(card->hw, XILINX_DMA_CONTROL_REG, reg); #ifdef DEBUG_INIT log(LOG_INFO, "--- Tx/Rx global enable. -- \n"); #endif xilinx_delay(1); reg = 0; sdla_bus_write_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, reg); /* Clear interrupt pending registers befor first interrupt enable */ sdla_bus_read_4(card->hw, XILINX_DMA_RX_INTR_PENDING_REG, &tmp); sdla_bus_read_4(card->hw, XILINX_DMA_TX_INTR_PENDING_REG, &tmp); sdla_bus_read_4(card->hw, XILINX_HDLC_RX_INTR_PENDING_REG, &tmp); sdla_bus_read_4(card->hw, XILINX_HDLC_TX_INTR_PENDING_REG, &tmp); sdla_bus_read_4(card->hw, XILINX_CHIP_CFG_REG, (u_int32_t *)®); if (bit_test((u_int8_t *)®, DMA_INTR_FLAG)) { log(LOG_INFO, "%s: Error: Active DMA Interrupt Pending. !\n", card->devname); reg = 0; /* Disable the chip/hdlc reset condition */ bit_set((u_int8_t *)®, CHIP_RESET_BIT); sdla_bus_write_4(card->hw, XILINX_CHIP_CFG_REG, reg); return (err); } if (bit_test((u_int8_t *)®, ERROR_INTR_FLAG)) { log(LOG_INFO, "%s: Error: Active Error Interrupt Pending. !\n", card->devname); reg = 0; /* Disable the chip/hdlc reset condition */ bit_set((u_int8_t *)®, CHIP_RESET_BIT); sdla_bus_write_4(card->hw, XILINX_CHIP_CFG_REG, reg); return (err); } /* Alawys disable global data and error interrupts */ bit_clear((u_int8_t *)®, GLOBAL_INTR_ENABLE_BIT); bit_clear((u_int8_t *)®, ERROR_INTR_ENABLE_BIT); /* Always enable the front end interrupt */ bit_set((u_int8_t *)®, FRONT_END_INTR_ENABLE_BIT); #ifdef DEBUG_INIT log(LOG_DEBUG, "--- Set Global Interrupts (0x%X)-- \n", reg); #endif xilinx_delay(1); sdla_bus_write_4(card->hw, XILINX_CHIP_CFG_REG, reg); return (err); } static int xilinx_chip_unconfigure(sdla_t *card) { u_int32_t reg = 0; sdla_bus_write_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, reg); sdla_bus_read_4(card->hw, XILINX_CHIP_CFG_REG, ®); /* Enable the chip/hdlc reset condition */ reg = 0; bit_set((u_int8_t *)®, CHIP_RESET_BIT); sdla_bus_write_4(card->hw, XILINX_CHIP_CFG_REG, reg); return (0); } static int xilinx_dev_configure(sdla_t *card, xilinx_softc_t *sc) { u_int32_t reg; long free_logic_ch, i; sc->logic_ch_num=-1; if (!IS_TE1(&card->fe_te.te_cfg)) return (EINVAL); if (IS_E1(&card->fe_te.te_cfg)) { log(LOG_DEBUG, "%s: Time Slot Orig 0x%lX Shifted 0x%lX\n", sc->if_name, sc->time_slot_map, sc->time_slot_map << 1); sc->time_slot_map = sc->time_slot_map << 1; bit_clear((u_int8_t *)&sc->time_slot_map, 0); } /* * Channel definition section. If not channels defined * return error */ if (sc->time_slot_map == 0) { log(LOG_INFO, "%s: Invalid Channel Selection 0x%lX\n", card->devname, sc->time_slot_map); return (EINVAL); } #ifdef DEBUG_INIT log(LOG_INFO, "%s:%s: Active channels = 0x%lX\n", card->devname, sc->if_name, sc->time_slot_map); #endif xilinx_delay(1); /* * Check that the time slot is not being used. If it is * stop the interface setup. Notice, though we proceed * to check for all timeslots before we start binding * the channels in. This way, we don't have to go back * and clean the time_slot_map */ for (i = 0; i < card->u.xilinx.num_of_time_slots; i++) { if (bit_test((u_int8_t *)&sc->time_slot_map, i)) { if (sc->first_time_slot == -1) { #ifdef DEBUG_INIT log(LOG_INFO, "%s: Setting first time " "slot to %ld\n", card->devname, i); #endif sc->first_time_slot = i; } #ifdef DEBUG_INIT log(LOG_DEBUG, "%s: Configuring %s for timeslot %ld\n", card->devname, sc->if_name, IS_E1(&card->fe_te.te_cfg)?i:i+1); #endif if (bit_test((u_int8_t *) &card->u.xilinx.time_slot_map, i)) { log(LOG_INFO, "%s: Channel/Time Slot " "resource conflict!\n", card->devname); log(LOG_INFO, "%s: %s: Channel/Time Slot " "%ld, aready in use!\n", card->devname, sc->if_name, (i+1)); return (EEXIST); } /* Calculate the number of timeslots for this if */ ++sc->num_of_time_slots; } } xilinx_delay(1); sc->logic_ch_num = request_xilinx_logical_channel_num(card, sc, &free_logic_ch); if (sc->logic_ch_num == -1) return (EBUSY); xilinx_delay(1); for (i = 0; i < card->u.xilinx.num_of_time_slots; i++) { if (bit_test((u_int8_t *)&sc->time_slot_map, i)) { bit_set((u_int8_t *)&card->u.xilinx.time_slot_map, i); sdla_bus_read_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, ®); reg &= ~TIMESLOT_BIT_MASK; /* FIXME do not hardcode !*/ reg &= HDLC_LCH_TIMESLOT_MASK; /* mask not valid bits*/ /* Select a Timeslot for configuration */ sdla_bus_write_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, (reg | (i << TIMESLOT_BIT_SHIFT))); reg = sc->logic_ch_num & CONTROL_RAM_DATA_MASK; #ifdef TRUE_FIFO_SIZE reg |= (sc->fifo_size_code & HDLC_FIFO_SIZE_MASK) << HDLC_FIFO_SIZE_SHIFT; #else reg |= (HARD_FIFO_CODE & HDLC_FIFO_SIZE_MASK) << HDLC_FIFO_SIZE_SHIFT; #endif /* TRUE_FIFO_SIZE */ reg |= (sc->fifo_base_addr & HDLC_FIFO_BASE_ADDR_MASK) << HDLC_FIFO_BASE_ADDR_SHIFT; #ifdef DEBUG_INIT log(LOG_INFO, "Setting Timeslot %ld to logic " "ch %ld Reg=0x%X\n", i, sc->logic_ch_num, reg); #endif xilinx_write_ctrl_hdlc(card, i, XILINX_CONTROL_RAM_ACCESS_BUF, reg); } } if (free_logic_ch != -1) { char free_ch_used = 0; for (i = 0; i < card->u.xilinx.num_of_time_slots; i++) { if (!bit_test((u_int8_t *) &card->u.xilinx.time_slot_map, i)) { sdla_bus_read_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, ®); reg &= ~TIMESLOT_BIT_MASK; /* mask not valid bits */ reg &= HDLC_LCH_TIMESLOT_MASK; /* Select a Timeslot for configuration */ sdla_bus_write_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, (reg | (i << TIMESLOT_BIT_SHIFT))); reg = free_logic_ch&CONTROL_RAM_DATA_MASK; /* For the rest of the unused logic channels * bind them to timeslot 31 and set the fifo * size to 32 byte = Code = 0x00 */ reg |= (FIFO_32B & HDLC_FIFO_SIZE_MASK) << HDLC_FIFO_SIZE_SHIFT; reg |= (free_logic_ch & HDLC_FIFO_BASE_ADDR_MASK) << HDLC_FIFO_BASE_ADDR_SHIFT; #ifdef DEBUG_INIT log(LOG_INFO, "Setting Timeslot " "%ld to free logic ch %ld Reg=0x%X\n", i, free_logic_ch, reg); #endif xilinx_write_ctrl_hdlc(card, i, XILINX_CONTROL_RAM_ACCESS_BUF, reg); free_ch_used = 1; } } /* We must check if the free logic has been bound * to any timeslots */ if (free_ch_used) { #ifdef DEBUG_INIT log(LOG_INFO, "%s: Setting Free CH %ld to idle\n", sc->if_name, free_logic_ch); #endif xilinx_delay(1); /* Setup the free logic channel as IDLE */ sdla_bus_read_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, ®); reg &= ~HDLC_LOGIC_CH_BIT_MASK; /* mask not valid bits */ reg &= HDLC_LCH_TIMESLOT_MASK; sdla_bus_write_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, (reg|(free_logic_ch&HDLC_LOGIC_CH_BIT_MASK))); reg = 0; bit_clear((u_int8_t *)®, HDLC_RX_PROT_DISABLE_BIT); bit_clear((u_int8_t *)®, HDLC_TX_PROT_DISABLE_BIT); bit_set((u_int8_t *)®, HDLC_RX_ADDR_RECOGN_DIS_BIT); xilinx_write_ctrl_hdlc(card, sc->first_time_slot, XILINX_HDLC_CONTROL_REG, reg); } } /* Select an HDLC logic channel for configuration */ sdla_bus_read_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, ®); reg &= ~HDLC_LOGIC_CH_BIT_MASK; reg &= HDLC_LCH_TIMESLOT_MASK; /* mask not valid bits */ sdla_bus_write_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, (reg | (sc->logic_ch_num & HDLC_LOGIC_CH_BIT_MASK))); reg = 0; /* HDLC engine is enabled on the above logical channels */ bit_clear((u_int8_t *)®, HDLC_RX_PROT_DISABLE_BIT); bit_clear((u_int8_t *)®, HDLC_TX_PROT_DISABLE_BIT); bit_set((u_int8_t *)®, HDLC_TX_CHAN_ENABLE_BIT); bit_set((u_int8_t *)®, HDLC_RX_ADDR_RECOGN_DIS_BIT); xilinx_write_ctrl_hdlc(card, sc->first_time_slot, XILINX_HDLC_CONTROL_REG, reg); return (0); } static void xilinx_dev_unconfigure(sdla_t *card, xilinx_softc_t *sc) { u_int32_t reg; int i, s; #ifdef DEBUG_INIT log(LOG_DEBUG, "\n-- Unconfigure Xilinx. --\n"); #endif /* Select an HDLC logic channel for configuration */ if (sc->logic_ch_num != -1) { sdla_bus_read_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, ®); reg &= ~HDLC_LOGIC_CH_BIT_MASK; reg &= HDLC_LCH_TIMESLOT_MASK; /* mask not valid bits */ sdla_bus_write_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, (reg | (sc->logic_ch_num & HDLC_LOGIC_CH_BIT_MASK))); reg = 0x00020000; xilinx_write_ctrl_hdlc(card, sc->first_time_slot, XILINX_HDLC_CONTROL_REG, reg); for (i = 0; i < card->u.xilinx.num_of_time_slots; i++) { if (bit_test((u_int8_t *)&sc->time_slot_map, i)) { sdla_bus_read_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, ®); reg &= ~TIMESLOT_BIT_MASK; /* mask not valid bits */ reg &= HDLC_LCH_TIMESLOT_MASK; /* Select a Timeslot for configuration */ sdla_bus_write_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, (reg | (i<logic_ch_num); for (i = 0; i < card->u.xilinx.num_of_time_slots; i++) if (bit_test((u_int8_t *)&sc->time_slot_map, i)) --sc->num_of_time_slots; free_fifo_baddr_and_size(card, sc); splx(s); sc->logic_ch_num = -1; for (i = 0; i < card->u.xilinx.num_of_time_slots; i++) if (bit_test((u_int8_t *)&sc->time_slot_map, i)) bit_clear((u_int8_t *) &card->u.xilinx.time_slot_map, i); } } #define FIFO_RESET_TIMEOUT_CNT 1000 #define FIFO_RESET_TIMEOUT_US 10 static int xilinx_init_rx_dev_fifo(sdla_t *card, xilinx_softc_t *sc, unsigned char wait) { u_int32_t reg; u_int32_t dma_descr; u_int8_t timeout = 1; u_int16_t i; /* Clean RX DMA fifo */ dma_descr = (unsigned long)(sc->logic_ch_num << 4) + XILINX_RxDMA_DESCRIPTOR_HI; reg = 0; bit_set((u_int8_t *)®, INIT_DMA_FIFO_CMD_BIT); #ifdef DEBUG_INIT log(LOG_DEBUG, "%s: Clearing RX Fifo DmaDescr=(0x%X) Reg=(0x%X) (%s)\n", sc->if_name, dma_descr, reg, __FUNCTION__); #endif sdla_bus_write_4(card->hw, dma_descr, reg); if (wait == WP_WAIT) { for (i = 0; i < FIFO_RESET_TIMEOUT_CNT; i++) { sdla_bus_read_4(card->hw, dma_descr, ®); if (bit_test((u_int8_t *)®, INIT_DMA_FIFO_CMD_BIT)) { DELAY(FIFO_RESET_TIMEOUT_US); continue; } timeout = 0; break; } #ifdef DEBUG_INIT if (timeout) log(LOG_INFO, "%s:%s: Error: Rx fifo reset " "timedout %u us\n", card->devname, sc->if_name, i * FIFO_RESET_TIMEOUT_US); else log(LOG_INFO, "%s:%s: Rx Fifo reset " "successful %u us\n", card->devname, sc->if_name, i * FIFO_RESET_TIMEOUT_US); #endif } else timeout = 0; return (timeout); } static int xilinx_init_tx_dev_fifo(sdla_t *card, xilinx_softc_t *sc, unsigned char wait) { u_int32_t reg; u_int32_t dma_descr; u_int8_t timeout = 1; u_int16_t i; /* Clean TX DMA fifo */ dma_descr = (unsigned long)(sc->logic_ch_num << 4) + XILINX_TxDMA_DESCRIPTOR_HI; reg = 0; bit_set((u_int8_t *)®, INIT_DMA_FIFO_CMD_BIT); #ifdef DEBUG_INIT log(LOG_DEBUG, "%s: Clearing TX Fifo DmaDescr=(0x%X) Reg=(0x%X) (%s)\n", sc->if_name, dma_descr, reg, __FUNCTION__); #endif sdla_bus_write_4(card->hw, dma_descr, reg); if (wait == WP_WAIT) { for (i = 0; i < FIFO_RESET_TIMEOUT_CNT; i++) { sdla_bus_read_4(card->hw, dma_descr, ®); if (bit_test((u_int8_t *)®, INIT_DMA_FIFO_CMD_BIT)) { DELAY(FIFO_RESET_TIMEOUT_US); continue; } timeout = 0; break; } #ifdef DEBUG_INIT if (timeout) log(LOG_INFO, "%s:%s: Error: Tx fifo reset " "timedout %u us\n", card->devname, sc->if_name, i * FIFO_RESET_TIMEOUT_US); else log(LOG_INFO, "%s:%s: Tx Fifo reset " "successful %u us\n", card->devname, sc->if_name, i * FIFO_RESET_TIMEOUT_US); #endif } else timeout = 0; return (timeout); } static void xilinx_dev_enable(sdla_t *card, xilinx_softc_t *sc) { u_int32_t reg; #ifdef DEBUG_INIT log(LOG_INFO, "%s: Enabling Global Inter Mask !\n", sc->if_name); #endif /* Enable Logic Channel Interrupts for DMA and fifo */ sdla_bus_read_4(card->hw, XILINX_GLOBAL_INTER_MASK, ®); bit_set((u_int8_t *)®, sc->logic_ch_num); sdla_bus_write_4(card->hw, XILINX_GLOBAL_INTER_MASK, reg); bit_set((u_int8_t *)&card->u.xilinx.active_ch_map, sc->logic_ch_num); } static void xilinx_dev_close(sdla_t *card, xilinx_softc_t *sc) { u_int32_t reg; unsigned long dma_descr; int s; #ifdef DEBUG_INIT log(LOG_DEBUG, "-- Close Xilinx device. --\n"); #endif /* Disable Logic Channel Interrupts for DMA and fifo */ sdla_bus_read_4(card->hw, XILINX_GLOBAL_INTER_MASK, ®); bit_clear((u_int8_t *)®, sc->logic_ch_num); bit_clear((u_int8_t *)&card->u.xilinx.active_ch_map, sc->logic_ch_num); /* * We are masking the sc interrupt. * Lock to make sure that the interrupt is * not running */ s = splnet(); sdla_bus_write_4(card->hw, XILINX_GLOBAL_INTER_MASK, reg); splx(s); reg = 0; /* Select an HDLC logic channel for configuration */ sdla_bus_read_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, ®); reg &= ~HDLC_LOGIC_CH_BIT_MASK; reg &= HDLC_LCH_TIMESLOT_MASK; /* mask not valid bits */ sdla_bus_write_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, (reg | (sc->logic_ch_num & HDLC_LOGIC_CH_BIT_MASK))); reg = 0; xilinx_write_ctrl_hdlc(card, sc->first_time_slot, XILINX_HDLC_CONTROL_REG, reg); /* Clear descriptors */ reg = 0; dma_descr=(sc->logic_ch_num<<4) + XILINX_RxDMA_DESCRIPTOR_HI; sdla_bus_write_4(card->hw, dma_descr, reg); dma_descr=(sc->logic_ch_num<<4) + XILINX_TxDMA_DESCRIPTOR_HI; sdla_bus_write_4(card->hw, dma_descr, reg); /* FIXME: Cleanp up Tx and Rx buffers */ } static int xilinx_dma_rx(sdla_t *card, xilinx_softc_t *sc) { u_int32_t reg; unsigned long dma_descr; unsigned long bus_addr; wp_rx_element_t *rx_el; /* sanity check: make sure that DMA is in ready state */ #if 0 dma_descr=(sc->logic_ch_num<<4) + XILINX_RxDMA_DESCRIPTOR_HI; sdla_bus_read_4(card->hw, dma_descr, ®); if (bit_test((u_int8_t *)®, RxDMA_HI_DMA_GO_READY_BIT)) { log(LOG_INFO, "%s: Error: RxDMA GO Ready bit set on dma Rx\n", card->devname); return (EFAULT); } #endif if (sc->rx_dma_buf) { log(LOG_INFO, "%s: Critial Error: Rx Dma Buf busy!\n", sc->if_name); return (EINVAL); } sc->rx_dma_buf = SIMPLEQ_FIRST(&sc->wp_rx_free_list); if (sc->rx_dma_buf == NULL) { if (aft_alloc_rx_dma_buff(sc, 1) == 0) { log(LOG_INFO, "%s: Critical Error no rx dma buf!", sc->if_name); return (ENOMEM); } sc->rx_dma_buf = SIMPLEQ_FIRST(&sc->wp_rx_free_list); } SIMPLEQ_REMOVE_HEAD(&sc->wp_rx_free_list, entry); bus_dmamap_sync(sc->dmatag, sc->rx_dma_buf->dma_map, 0, sc->dma_mtu, BUS_DMASYNC_PREREAD); rx_el = &sc->rx_dma_buf->rx_el; memset(rx_el, 0, sizeof(*rx_el)); bus_addr = sc->rx_dma_buf->dma_map->dm_segs[0].ds_addr; rx_el->dma_addr = bus_addr; /* Write the pointer of the data packet to the * DMA address register */ reg = bus_addr; /* Set the 32bit alignment of the data length. * Since we are setting up for rx, set this value * to Zero */ reg &= ~(RxDMA_LO_ALIGNMENT_BIT_MASK); dma_descr = (sc->logic_ch_num<<4) + XILINX_RxDMA_DESCRIPTOR_LO; #ifdef DEBUG_RX log(LOG_INFO, "%s: RxDMA_LO = 0x%X, BusAddr=0x%lX " "DmaDescr=0x%lX (%s)\n", card->devname, reg, bus_addr, dma_descr, __FUNCTION__); #endif sdla_bus_write_4(card->hw, dma_descr, reg); dma_descr=(unsigned long)(sc->logic_ch_num << 4) + XILINX_RxDMA_DESCRIPTOR_HI; reg = 0; reg |= (sc->dma_mtu >> 2) & RxDMA_HI_DMA_DATA_LENGTH_MASK; #ifdef TRUE_FIFO_SIZE reg |= (sc->fifo_size_code & DMA_FIFO_SIZE_MASK) << DMA_FIFO_SIZE_SHIFT; #else reg |= (HARD_FIFO_CODE & DMA_FIFO_SIZE_MASK) << DMA_FIFO_SIZE_SHIFT; #endif reg |= (sc->fifo_base_addr&DMA_FIFO_BASE_ADDR_MASK) << DMA_FIFO_BASE_ADDR_SHIFT; bit_set((u_int8_t *)®, RxDMA_HI_DMA_GO_READY_BIT); #ifdef DEBUG_RX log(LOG_INFO, "%s: RXDMA_HI = 0x%X, BusAddr=0x%lX DmaDescr=0x%lX " "(%s)\n", sc->if_name, reg, bus_addr, dma_descr, __FUNCTION__); #endif sdla_bus_write_4(card->hw, dma_descr, reg); bit_set((u_int8_t *)&sc->rx_dma, 0); return (0); } static int xilinx_dma_tx(sdla_t *card, xilinx_softc_t *sc) { u_int32_t reg = 0; struct mbuf *m; unsigned long dma_descr; unsigned char len_align = 0; int len = 0; #ifdef DEBUG_TX log(LOG_INFO, "------ Setup Tx DMA descriptor. --\n"); #endif if (bit_test((u_int8_t *)&sc->dma_status, TX_BUSY)) { #ifdef DEBUG_TX log(LOG_INFO, "%s: TX_BUSY set (%s:%d)!\n", sc->if_name, __FUNCTION__, __LINE__); #endif return EBUSY; } bit_set((u_int8_t *)&sc->dma_status, TX_BUSY); /* * Free the previously skb dma mapping. * In this case the tx interrupt didn't finish and we must re-transmit. */ if (sc->tx_dma_addr && sc->tx_dma_len) { log(LOG_INFO, "%s: Unmaping tx_dma_addr in %s\n", sc->if_name, __FUNCTION__); sc->tx_dma_addr = 0; sc->tx_dma_len = 0; } /* Free the previously sent tx packet. To * minimize tx isr, the previously transmitted * packet is deallocated here */ if (sc->tx_dma_mbuf) { bus_dmamap_unload(sc->dmatag, sc->tx_dmamap); m_freem(sc->tx_dma_mbuf); sc->tx_dma_mbuf = NULL; } /* check queue pointers before starting transmission */ /* sanity check: make sure that DMA is in ready state */ dma_descr = (sc->logic_ch_num << 4) + XILINX_TxDMA_DESCRIPTOR_HI; #ifdef DEBUG_TX log(LOG_INFO, "%s: sc logic ch=%ld dma_descr=0x%lx set (%s:%d)!\n", sc->if_name, sc->logic_ch_num, dma_descr, __FUNCTION__, __LINE__); #endif sdla_bus_read_4(card->hw, dma_descr, ®); if (bit_test((u_int8_t *)®, TxDMA_HI_DMA_GO_READY_BIT)) { log(LOG_INFO, "%s: Error: TxDMA GO Ready bit set " "on dma Tx 0x%X\n", card->devname, reg); bit_clear((u_int8_t *)&sc->dma_status, TX_BUSY); return (EFAULT); } IF_DEQUEUE(&sc->wp_tx_pending_list, m); if (!m) { bit_clear((u_int8_t *)&sc->dma_status, TX_BUSY); return (ENOBUFS); } len = m->m_len; if (len > MAX_XILINX_TX_DMA_SIZE) { /* FIXME: We need to split this frame into * multiple parts. For now though * just drop it :) */ log(LOG_INFO, "%s: Tx len %d > %d (MAX TX DMA LEN)\n", sc->if_name, len, MAX_XILINX_TX_DMA_SIZE); m_freem(m); bit_clear((u_int8_t *)&sc->dma_status, TX_BUSY); return (EINVAL); } if (ADDR_MASK(mtod(m, caddr_t), 0x03)) { /* The mbuf should already be aligned */ log(LOG_INFO, "%s: TX packet not aligned!\n", sc->if_name); m_freem(m); bit_clear((u_int8_t *)&sc->dma_status, TX_BUSY); return (EINVAL); } if (bus_dmamap_load(sc->dmatag, sc->tx_dmamap, mtod(m, void *), len, NULL, BUS_DMA_NOWAIT | BUS_DMA_WRITE)) { log(LOG_INFO, "%s: Failed to load TX mbuf for DMA!\n", sc->if_name); m_freem(m); bit_clear((u_int8_t *)&sc->dma_status, TX_BUSY); return (EINVAL); } sc->tx_dma_addr = sc->tx_dmamap->dm_segs[0].ds_addr; sc->tx_dma_len = len; if (sc->tx_dma_addr & 0x03) { log(LOG_INFO, "%s: Error: Tx Ptr not aligned " "to 32bit boundary!\n", card->devname); m_freem(m); bit_clear((u_int8_t *)&sc->dma_status, TX_BUSY); return (EINVAL); } sc->tx_dma_mbuf = m; /* WARNING: Do not use the "skb" pointer from * here on. The skb pointer might not exist if * we are in transparent mode */ dma_descr = (sc->logic_ch_num << 4) + XILINX_TxDMA_DESCRIPTOR_LO; /* Write the pointer of the data packet to the * DMA address register */ reg = sc->tx_dma_addr; bus_dmamap_sync(sc->dmatag, sc->tx_dmamap, 0, len, BUS_DMASYNC_PREWRITE); /* Set the 32bit alignment of the data length. * Used to pad the tx packet to the 32 bit * boundary */ reg &= ~(TxDMA_LO_ALIGNMENT_BIT_MASK); reg |= (len & 0x03); if (len & 0x03) len_align = 1; #ifdef DEBUG_TX log(LOG_INFO, "%s: TXDMA_LO=0x%X PhyAddr=0x%lX DmaDescr=0x%lX (%s)\n", sc->if_name, reg, sc->tx_dma_addr, dma_descr, __FUNCTION__); #endif sdla_bus_write_4(card->hw, dma_descr, reg); dma_descr = (sc->logic_ch_num << 4) + XILINX_TxDMA_DESCRIPTOR_HI; reg = 0; reg |= (((len >> 2) + len_align) & TxDMA_HI_DMA_DATA_LENGTH_MASK); #ifdef TRUE_FIFO_SIZE reg |= (sc->fifo_size_code & DMA_FIFO_SIZE_MASK) << DMA_FIFO_SIZE_SHIFT; #else reg |= (HARD_FIFO_CODE & DMA_FIFO_SIZE_MASK) << DMA_FIFO_SIZE_SHIFT; #endif reg |= (sc->fifo_base_addr & DMA_FIFO_BASE_ADDR_MASK) << DMA_FIFO_BASE_ADDR_SHIFT; /* * Only enable the Frame Start/Stop on * non-transparent hdlc configuration */ bit_set((u_int8_t *)®, TxDMA_HI_DMA_FRAME_START_BIT); bit_set((u_int8_t *)®, TxDMA_HI_DMA_FRAME_END_BIT); bit_set((u_int8_t *)®, TxDMA_HI_DMA_GO_READY_BIT); #ifdef DEBUG_TX log(LOG_INFO, "%s: TXDMA_HI=0x%X DmaDescr=0x%lX (%s)\n", sc->if_name, reg, dma_descr, __FUNCTION__); #endif sdla_bus_write_4(card->hw, dma_descr, reg); return (0); } static void xilinx_dma_tx_complete(sdla_t *card, xilinx_softc_t *sc) { u_int32_t reg = 0; unsigned long dma_descr; #ifdef DEBUG_TX log(LOG_INFO, "%s: TX DMA complete\n", card->devname); #endif /* DEBUGTX */ /* sdla_bus_read_4(card->hw, 0x78, &tmp1); */ dma_descr = (sc->logic_ch_num << 4) + XILINX_TxDMA_DESCRIPTOR_HI; sdla_bus_read_4(card->hw, dma_descr, ®); if (sc->tx_dma_mbuf == NULL) { log(LOG_INFO, "%s: Critical Error: Tx DMA intr: no tx mbuf !\n", card->devname); bit_clear((u_int8_t *)&sc->dma_status, TX_BUSY); return; } bus_dmamap_sync(sc->dmatag, sc->tx_dmamap, 0, sc->tx_dma_len, BUS_DMASYNC_POSTWRITE); sc->tx_dma_addr = 0; sc->tx_dma_len = 0; /* Do not free the packet here, * copy the packet dma info into csum * field and let the bh handler analyze * the transmitted packet. */ if (reg & TxDMA_HI_DMA_PCI_ERROR_RETRY_TOUT) { log(LOG_INFO, "%s:%s: PCI Error: 'Retry' " "exceeds maximum (64k): Reg=0x%X!\n", card->devname, sc->if_name, reg); if (++sc->pci_retry < 3) { bit_set((u_int8_t *)®, TxDMA_HI_DMA_GO_READY_BIT); log(LOG_INFO, "%s: Retry: TXDMA_HI=0x%X " "DmaDescr=0x%lX (%s)\n", sc->if_name, reg, dma_descr, __FUNCTION__); sdla_bus_write_4(card->hw, dma_descr, reg); return; } } sc->pci_retry = 0; sc->tx_dma_mbuf->m_pkthdr.csum_flags = reg & 0xFFFF; sc->tx_dma_mbuf->m_pkthdr.ether_vtag = (reg >> 16) & 0xFFFF; IF_ENQUEUE(&sc->wp_tx_complete_list, sc->tx_dma_mbuf); sc->tx_dma_mbuf = NULL; bit_clear((u_int8_t *)&sc->dma_status, TX_BUSY); xilinx_process_packet(sc); } static void xilinx_tx_post_complete(sdla_t *card, xilinx_softc_t *sc, struct mbuf *m) { struct ifnet *ifp; u_int32_t reg; WAN_ASSERT1(sc == NULL); reg = (m->m_pkthdr.ether_vtag << 16) + m->m_pkthdr.csum_flags; ifp = (struct ifnet *)&sc->common.ifp; if ((bit_test((u_int8_t *)®, TxDMA_HI_DMA_GO_READY_BIT)) || (reg & TxDMA_HI_DMA_DATA_LENGTH_MASK) || (reg & TxDMA_HI_DMA_PCI_ERROR_MASK)) { #ifdef DEBUG_TX log(LOG_INFO, "%s:%s: Tx DMA Descriptor=0x%lX\n", card->devname, sc->if_name, reg); #endif /* Checking Tx DMA Go bit. Has to be '0' */ if (bit_test((u_int8_t *)®, TxDMA_HI_DMA_GO_READY_BIT)) log(LOG_INFO, "%s:%s: Error: TxDMA Intr: " "GO bit set on Tx intr\n", card->devname, sc->if_name); if (reg & TxDMA_HI_DMA_DATA_LENGTH_MASK) log(LOG_INFO, "%s:%s: Error: TxDMA Length " "not equal 0 \n", card->devname, sc->if_name); /* Checking Tx DMA PCI error status. Has to be '0's */ if (reg & TxDMA_HI_DMA_PCI_ERROR_MASK) { if (reg & TxDMA_HI_DMA_PCI_ERROR_M_ABRT) log(LOG_INFO, "%s:%s: Tx Error: " "Abort from Master: pci fatal error!\n", card->devname, sc->if_name); if (reg & TxDMA_HI_DMA_PCI_ERROR_T_ABRT) log(LOG_INFO, "%s:%s: Tx Error: " "Abort from Target: pci fatal error!\n", card->devname, sc->if_name); if (reg & TxDMA_HI_DMA_PCI_ERROR_DS_TOUT) { log(LOG_INFO, "%s:%s: Tx Warning: " "PCI Latency Timeout!\n", card->devname, sc->if_name); goto tx_post_ok; } if (reg & TxDMA_HI_DMA_PCI_ERROR_RETRY_TOUT) log(LOG_INFO, "%s:%s: Tx Error: 'Retry' " "exceeds maximum (64k): pci fatal error!\n", card->devname, sc->if_name); } goto tx_post_exit; } tx_post_ok: if (ifp) ifp->if_opackets++; /* Indicate that the first tx frame went * out on the transparent link */ bit_set((u_int8_t *)&sc->idle_start, 0); tx_post_exit: if (!xilinx_dma_tx(card, sc)) { /* * If we were able to transmit and the interface is set to * OACTIVE remove this flag and let kernel try to transmit. */ if (ifp->if_flags & IFF_OACTIVE) ifp->if_flags &= ~IFF_OACTIVE; } return; } static void xilinx_dma_rx_complete(sdla_t *card, xilinx_softc_t *sc) { struct xilinx_rx_buffer *buf; unsigned long dma_descr; wp_rx_element_t *rx_el; bit_clear((u_int8_t *)&sc->rx_dma, 0); if (sc->rx_dma_buf == NULL) { log(LOG_INFO, "%s: Critical Error: rx_dma_mbuf\n", sc->if_name); return; } rx_el = &sc->rx_dma_buf->rx_el; /* Reading Rx DMA descriptor information */ dma_descr=(sc->logic_ch_num << 4) + XILINX_RxDMA_DESCRIPTOR_LO; sdla_bus_read_4(card->hw, dma_descr, &rx_el->align); rx_el->align &= RxDMA_LO_ALIGNMENT_BIT_MASK; dma_descr = (sc->logic_ch_num << 4) + XILINX_RxDMA_DESCRIPTOR_HI; sdla_bus_read_4(card->hw, dma_descr, &rx_el->reg); rx_el->pkt_error = sc->pkt_error; sc->pkt_error = 0; #ifdef DEBUG_RX log(LOG_INFO, "%s: RX HI=0x%X LO=0x%X DMA=0x%lX (%s:%d)\n", sc->if_name, rx_el->reg, rx_el->align, rx_el->dma_addr, __FUNCTION__, __LINE__); #endif buf = sc->rx_dma_buf; sc->rx_dma_buf = NULL; xilinx_dma_rx(card, sc); SIMPLEQ_INSERT_TAIL(&sc->wp_rx_complete_list, buf, entry); xilinx_process_packet(sc); /* sdla_bus_read_4(card->hw, 0x80, &rx_empty); */ } static void xilinx_rx_post_complete(sdla_t *card, xilinx_softc_t *sc, struct xilinx_rx_buffer *buf, struct mbuf **new_m, u_char *pkt_error) { struct ifnet *ifp; unsigned int len, data_error = 0; wp_rx_element_t *rx_el = &buf->rx_el; struct mbuf *m = buf->mbuf; WAN_ASSERT1(sc == NULL); ifp = (struct ifnet *)&sc->common.ifp; /*m->m_pkthdr.rcvif;*/ #ifdef DEBUG_RX log(LOG_INFO, "%s: RX HI=0x%X LO=0x%X DMA=0x%lX (%s:%d)\n", sc->if_name, rx_el->reg, rx_el->align, rx_el->dma_addr, __FUNCTION__, __LINE__); #endif rx_el->align &= RxDMA_LO_ALIGNMENT_BIT_MASK; *pkt_error = 0; *new_m = NULL; /* Checking Rx DMA Go bit. Has to be '0' */ if (bit_test((u_int8_t *)&rx_el->reg, RxDMA_HI_DMA_GO_READY_BIT)) { log(LOG_INFO, "%s: Error: RxDMA Intr: GO bit set on Rx intr\n", card->devname); ifp->if_ierrors++; goto rx_comp_error; } /* Checking Rx DMA PCI error status. Has to be '0's */ if (rx_el->reg & RxDMA_HI_DMA_PCI_ERROR_MASK) { #ifdef DEBUG_ERR if (rx_el->reg & RxDMA_HI_DMA_PCI_ERROR_M_ABRT) log(LOG_INFO, "%s: Rx Error: Abort from Master: " "pci fatal error!\n", card->devname); if (rx_el->reg & RxDMA_HI_DMA_PCI_ERROR_T_ABRT) log(LOG_INFO, "%s: Rx Error: Abort from Target: " "pci fatal error!\n", card->devname); if (rx_el->reg & RxDMA_HI_DMA_PCI_ERROR_DS_TOUT) log(LOG_INFO, "%s: Rx Error: No 'DeviceSelect' " "from target: pci fatal error!\n", card->devname); if (rx_el->reg & RxDMA_HI_DMA_PCI_ERROR_RETRY_TOUT) log(LOG_INFO, "%s: Rx Error: 'Retry' exceeds maximum " "(64k): pci fatal error!\n", card->devname); log(LOG_INFO, "%s: RXDMA PCI ERROR = 0x%x\n", card->devname, rx_el->reg); #endif if (ifp) ifp->if_ierrors++; goto rx_comp_error; } /* Checking Rx DMA Frame start bit. (information for api) */ if (!bit_test((u_int8_t *)&rx_el->reg, RxDMA_HI_DMA_FRAME_START_BIT)) { #ifdef DEBUG_ERR log(LOG_INFO, "%s: RxDMA Intr: Start flag missing: " "MTU Mismatch! Reg=0x%X\n", card->devname, rx_el->reg); #endif if (ifp) ifp->if_ierrors++; goto rx_comp_error; } /* Checking Rx DMA Frame end bit. (information for api) */ if (!bit_test((u_int8_t *)&rx_el->reg, RxDMA_HI_DMA_FRAME_END_BIT)) { #ifdef DEBUG_ERR log(LOG_INFO, "%s: RxDMA Intr: End flag missing: " "MTU Mismatch! Reg=0x%X\n", card->devname, rx_el->reg); #endif if (ifp) ifp->if_ierrors++; goto rx_comp_error; } else { /* Check CRC error flag only if this is the end of Frame */ if (bit_test((u_int8_t *)&rx_el->reg, RxDMA_HI_DMA_CRC_ERROR_BIT)) { #ifdef DEBUG_ERR log(LOG_INFO, "%s: RxDMA Intr: CRC Error! Reg=0x%X\n", card->devname, rx_el->reg); #endif if (ifp) ifp->if_ierrors++; bit_set((u_int8_t *)&rx_el->pkt_error, WP_CRC_ERROR_BIT); data_error = 1; } /* Check if this frame is an abort, if it is * drop it and continue receiving */ if (bit_test((u_int8_t *)&rx_el->reg, RxDMA_HI_DMA_FRAME_ABORT_BIT)) { #ifdef DEBUG_ERR log(LOG_INFO, "%s: RxDMA Intr: Abort! Reg=0x%X\n", card->devname, rx_el->reg); #endif if (ifp) ifp->if_ierrors++; bit_set((u_int8_t *)&rx_el->pkt_error, WP_ABORT_ERROR_BIT); data_error = 1; } if (data_error) goto rx_comp_error; } len = rx_el->reg & RxDMA_HI_DMA_DATA_LENGTH_MASK; /* In HDLC mode, calculate rx length based * on alignment value, received from DMA */ len = (((sc->dma_mtu >> 2) - len) << 2) - (~(rx_el->align) & RxDMA_LO_ALIGNMENT_BIT_MASK); *pkt_error = rx_el->pkt_error; /* After a RX FIFO overflow, we must mark max 7 * subsequent frames since firmware, cannot * guarantee the contents of the fifo */ if (bit_test((u_int8_t *)&rx_el->pkt_error, WP_FIFO_ERROR_BIT)) { if (++sc->rx_fifo_err_cnt >= WP_MAX_FIFO_FRAMES) { sc->rx_fifo_err_cnt = 0; } bit_set((u_int8_t *)pkt_error, WP_FIFO_ERROR_BIT); } else { if (sc->rx_fifo_err_cnt) { if (++sc->rx_fifo_err_cnt >= WP_MAX_FIFO_FRAMES) { sc->rx_fifo_err_cnt = 0; } bit_set((u_int8_t *)pkt_error, WP_FIFO_ERROR_BIT); } } bus_dmamap_sync(sc->dmatag, sc->rx_dma_buf->dma_map, 0, len, BUS_DMASYNC_POSTREAD); m->m_len = m->m_pkthdr.len = len; if (len > aft_rx_copyback) { /* The rx size is big enough, thus * send this buffer up the stack * and allocate another one */ *new_m = m; buf->mbuf = NULL; } else { struct mbuf *m0; /* The rx packet is very * small thus, allocate a new * buffer and pass it up */ if ((m0 = m_copym2(m, 0, len, M_NOWAIT)) == NULL) { log(LOG_INFO, "%s: Failed to allocate mbuf!\n", sc->if_name); if (ifp) ifp->if_ierrors++; } else *new_m = m0; } rx_comp_error: aft_reload_rx_dma_buff(sc, buf); return; } static char request_xilinx_logical_channel_num(sdla_t *card, xilinx_softc_t *sc, long *free_ch) { char logic_ch = -1, free_logic_ch = -1; int i, err; *free_ch = -1; #ifdef DEBUG_INIT log(LOG_INFO, "-- Request_Xilinx_logic_channel_num:--\n"); log(LOG_INFO, "%s: Global Num Timeslots=%d " "Global Logic ch Map 0x%lX (%s:%d)\n", sc->if_name, card->u.xilinx.num_of_time_slots, card->u.xilinx.logic_ch_map, __FUNCTION__, __LINE__); #endif err = request_fifo_baddr_and_size(card, sc); if (err) return (-1); for (i = 0; i < card->u.xilinx.num_of_time_slots; i++) { if (!bit_test((u_int8_t *)&card->u.xilinx.logic_ch_map, i)) { bit_set((u_int8_t *)&card->u.xilinx.logic_ch_map, i); logic_ch = i; break; } } if (logic_ch == -1) return (logic_ch); for (i = 0; i < card->u.xilinx.num_of_time_slots; i++) { if (!bit_test((u_int8_t *)&card->u.xilinx.logic_ch_map, i)) { free_logic_ch = HDLC_FREE_LOGIC_CH; break; } } if (card->u.xilinx.dev_to_ch_map[(unsigned char)logic_ch]) { log(LOG_INFO, "%s: Error, request logical ch=%d map busy\n", card->devname, logic_ch); return (-1); } *free_ch = free_logic_ch; card->u.xilinx.dev_to_ch_map[(unsigned char)logic_ch] = (void *)sc; if (logic_ch > card->u.xilinx.top_logic_ch) { card->u.xilinx.top_logic_ch = logic_ch; xilinx_dma_max_logic_ch(card); } return (logic_ch); } static void free_xilinx_logical_channel_num(sdla_t *card, int logic_ch) { bit_clear((u_int8_t *)&card->u.xilinx.logic_ch_map, logic_ch); card->u.xilinx.dev_to_ch_map[logic_ch] = NULL; if (logic_ch >= card->u.xilinx.top_logic_ch) { int i; card->u.xilinx.top_logic_ch = XILINX_DEFLT_ACTIVE_CH; for (i = 0; i < card->u.xilinx.num_of_time_slots; i++) { if (card->u.xilinx.dev_to_ch_map[logic_ch]) card->u.xilinx.top_logic_ch = i; } xilinx_dma_max_logic_ch(card); } } static void xilinx_dma_max_logic_ch(sdla_t *card) { u_int32_t reg; #ifdef DEBUG_INIT log(LOG_INFO, "-- Xilinx_dma_max_logic_ch :--\n"); #endif sdla_bus_read_4(card->hw, XILINX_DMA_CONTROL_REG, ®); /* Set up the current highest active logic channel */ reg &= DMA_ACTIVE_CHANNEL_BIT_MASK; reg |= (card->u.xilinx.top_logic_ch << DMA_ACTIVE_CHANNEL_BIT_SHIFT); sdla_bus_write_4(card->hw, XILINX_DMA_CONTROL_REG, reg); } static int aft_alloc_rx_buffers(xilinx_softc_t *sc) { struct xilinx_rx_buffer *buf; SIMPLEQ_INIT(&sc->wp_rx_free_list); SIMPLEQ_INIT(&sc->wp_rx_complete_list); /* allocate receive buffers in one cluster */ buf = malloc(sizeof(*buf) * MAX_RX_BUF, M_DEVBUF, M_NOWAIT | M_ZERO); if (buf == NULL) return (1); sc->wp_rx_buffers = buf; sc->wp_rx_buffer_last = buf; return (0); } static void aft_release_rx_buffers(xilinx_softc_t *sc) { struct xilinx_rx_buffer *buf; if (sc->wp_rx_buffers == NULL) return; while ((buf = SIMPLEQ_FIRST(&sc->wp_rx_free_list)) != NULL) { SIMPLEQ_REMOVE_HEAD(&sc->wp_rx_free_list, entry); aft_release_rx_dma_buff(sc, buf); } while ((buf = SIMPLEQ_FIRST(&sc->wp_rx_complete_list)) != NULL) { SIMPLEQ_REMOVE_HEAD(&sc->wp_rx_complete_list, entry); aft_release_rx_dma_buff(sc, buf); } free(sc->wp_rx_buffers, M_DEVBUF, 0); sc->wp_rx_buffers = NULL; sc->wp_rx_buffer_last = NULL; } /* Allocate an mbuf and setup dma_map. */ static int aft_alloc_rx_dma_buff(xilinx_softc_t *sc, int num) { struct xilinx_rx_buffer *buf, *ebuf; int n; ebuf = sc->wp_rx_buffers + MAX_RX_BUF; buf = sc->wp_rx_buffer_last; for (n = 0; n < num; n++) { int i; for (i = 0; i < MAX_RX_BUF; i++) { if (buf->mbuf == NULL) break; if (++buf == ebuf) buf = sc->wp_rx_buffers; } if (buf->mbuf != NULL) break; sc->wp_rx_buffer_last = buf; buf->mbuf = wan_mbuf_alloc(sc->dma_mtu); if (buf->mbuf == NULL) break; if (bus_dmamap_create(sc->dmatag, sc->dma_mtu, 1, sc->dma_mtu, 0, BUS_DMA_NOWAIT | BUS_DMA_ALLOCNOW, &buf->dma_map)) { m_freem(buf->mbuf); buf->mbuf = NULL; break; } if (bus_dmamap_load(sc->dmatag, buf->dma_map, mtod(buf->mbuf, void *), sc->dma_mtu, NULL, BUS_DMA_NOWAIT | BUS_DMA_READ)) { aft_release_rx_dma_buff(sc, buf); break; } SIMPLEQ_INSERT_TAIL(&sc->wp_rx_free_list, buf, entry); } return (n); } static void aft_reload_rx_dma_buff(xilinx_softc_t *sc, struct xilinx_rx_buffer *buf) { bus_dmamap_unload(sc->dmatag, buf->dma_map); if (buf->mbuf == NULL) { buf->mbuf = wan_mbuf_alloc(sc->dma_mtu); if (buf->mbuf == NULL) { bus_dmamap_destroy(sc->dmatag, buf->dma_map); return; } } if (bus_dmamap_load(sc->dmatag, buf->dma_map, mtod(buf->mbuf, void *), sc->dma_mtu, NULL, BUS_DMA_NOWAIT | BUS_DMA_READ)) { aft_release_rx_dma_buff(sc, buf); return; } SIMPLEQ_INSERT_TAIL(&sc->wp_rx_free_list, buf, entry); } static void aft_release_rx_dma_buff(xilinx_softc_t *sc, struct xilinx_rx_buffer *buf) { bus_dmamap_destroy(sc->dmatag, buf->dma_map); m_freem(buf->mbuf); buf->mbuf = NULL; } static void enable_timer(void *card_id) { sdla_t *card = (sdla_t *)card_id; int s; s = splnet(); sdla_te_polling(card); splx(s); return; } static void xilinx_process_packet(xilinx_softc_t *sc) { struct ifnet *ifp; struct mbuf *new_m, *m; unsigned char pkt_error; WAN_ASSERT1(sc == NULL); for (;;) { struct xilinx_rx_buffer *buf; buf = SIMPLEQ_FIRST(&sc->wp_rx_complete_list); if (buf == NULL) break; SIMPLEQ_REMOVE_HEAD(&sc->wp_rx_complete_list, entry); new_m = NULL; pkt_error = 0; xilinx_rx_post_complete(sc->common.card, sc, buf, &new_m, &pkt_error); if (new_m) { ifp = (struct ifnet *)&sc->common.ifp; #ifdef DEBUG_RX log(LOG_INFO, "%s: Receiving packet %d bytes!\n", ifp->if_xname, new_m->m_len); #endif wanpipe_generic_input(ifp, new_m); } } for (;;) { IF_DEQUEUE(&sc->wp_tx_complete_list, m); if (m == NULL) break; xilinx_tx_post_complete(sc->common.card, sc, m); m_freem(m); } return; } static int fifo_error_interrupt(sdla_t *card, unsigned long reg) { u_int32_t rx_status, tx_status; u_int32_t err = 0; u_int32_t i; xilinx_softc_t *sc; #ifdef DEBUG_ERR log(LOG_INFO, "%s: Fifo error interrupt!\n", card->devname); #endif /* Clear HDLC pending registers */ sdla_bus_read_4(card->hw, XILINX_HDLC_TX_INTR_PENDING_REG, &tx_status); sdla_bus_read_4(card->hw, XILINX_HDLC_RX_INTR_PENDING_REG, &rx_status); if (card->state != WAN_CONNECTED) { log(LOG_INFO, "%s: Warning: Ignoring Error Intr: link disc!\n", card->devname); return (0); } tx_status &= card->u.xilinx.active_ch_map; rx_status &= card->u.xilinx.active_ch_map; if (tx_status != 0) { for (i = 0; i < card->u.xilinx.num_of_time_slots; i++) { if (bit_test((u_int8_t *)&tx_status, i) && bit_test((u_int8_t *)&card->u.xilinx.logic_ch_map, i)) { struct ifnet *ifp; sc = (xilinx_softc_t *) card->u.xilinx.dev_to_ch_map[i]; if (!sc) { log(LOG_INFO, "Warning: ignoring tx " "error intr: no dev!\n"); continue; } ifp = (struct ifnet *)&sc->common.ifp; #if 0 if (!(ifp->if_flags & IFF_UP)) { log(LOG_INFO, "%s: Warning: ignoring " "tx error intr: dev down 0x%X " "UP=0x%X!\n", ifp->if_xname, sc->common.state, sc->ignore_modem); continue; } #endif if (card->state != WAN_CONNECTED) { log(LOG_INFO, "%s: Warning: ignoring " "tx error intr: dev disc!\n", ifp->if_xname); continue; } #ifdef DEBUG_ERR log(LOG_INFO, "%s:%s: Warning TX Fifo Error " "on LogicCh=%ld Slot=%d!\n", card->devname, sc->if_name, sc->logic_ch_num, i); #endif xilinx_tx_fifo_under_recover(card, sc); err=EINVAL; } } } if (rx_status != 0) { for (i = 0; i < card->u.xilinx.num_of_time_slots; i++) { if (bit_test((u_int8_t *)&rx_status, i) && bit_test((u_int8_t *)&card->u.xilinx.logic_ch_map, i)) { struct ifnet *ifp; sc = (xilinx_softc_t *) card->u.xilinx.dev_to_ch_map[i]; if (!sc) continue; ifp = (struct ifnet *)&sc->common.ifp; #if 0 if (!(ifp->if_flags & IFF_UP)) { log(LOG_INFO, "%s: Warning: ignoring " "rx error intr: dev down " "0x%X UP=0x%X!\n", ifp->if_xname, sc->common.state, sc->ignore_modem); continue; } #endif if (card->state != WAN_CONNECTED) { log(LOG_INFO, "%s: Warning: ignoring " "rx error intr: dev disc!\n", ifp->if_xname); continue; } #ifdef DEBUG_ERR log(LOG_INFO, "%s:%s: Warning RX Fifo Error " "on LCh=%ld Slot=%d RxDMA=%d\n", card->devname, sc->if_name, sc->logic_ch_num, i, sc->rx_dma); #endif #if 0 { unsigned long dma_descr; unsigned int reg; dma_descr = (sc->logic_ch_num << 4) + XILINX_RxDMA_DESCRIPTOR_HI; sdla_bus_read_4(card->hw, dma_descr, ®); log(LOG_INFO, "%s: Hi Descriptor 0x%X\n", sc->if_name, reg); } #endif bit_set((u_int8_t *)&sc->pkt_error, WP_FIFO_ERROR_BIT); err = EINVAL; } } } return (err); } static void front_end_interrupt(sdla_t *card, unsigned long reg) { sdla_te_intr(card); handle_front_end_state(card); return; } /* * HARDWARE Interrupt Handlers */ /* * Main interrupt service routine. * Determine the interrupt received and handle it. */ static void wp_xilinx_isr(sdla_t* card) { int i; u_int32_t reg; u_int32_t dma_tx_reg, dma_rx_reg; xilinx_softc_t *sc; if (bit_test((u_int8_t *)&card->critical, CARD_DOWN)) { log(LOG_INFO, "%s: Card down, ignoring interrupt !!!!!!!!\n", card->devname); return; } bit_set((u_int8_t *)&card->in_isr, 0); /* write_cpld(card, LED_CONTROL_REG, 0x0F);*/ /* * Disable all chip Interrupts (offset 0x040) * -- "Transmit/Receive DMA Engine" interrupt disable * -- "FiFo/Line Abort Error" interrupt disable */ sdla_bus_read_4(card->hw, XILINX_CHIP_CFG_REG, ®); if (bit_test((u_int8_t *)®, SECURITY_STATUS_FLAG)) { log(LOG_INFO, "%s: Critical: Chip Security Compromised!\n", card->devname); log(LOG_INFO, "%s: Disabling Driver!\n", card->devname); port_set_state(card, WAN_DISCONNECTED); disable_data_error_intr(card, CARD_DOWN); goto isr_end; } /* * Note: If interrupts are received without pending flags, it usually * indicates that the interrupt * is being shared. */ if (bit_test((u_int8_t *)®, FRONT_END_INTR_ENABLE_BIT)) { if (bit_test((u_int8_t *)®, FRONT_END_INTR_FLAG)) { front_end_interrupt(card, reg); if (card->u.xilinx.state_change_exit_isr) { card->u.xilinx.state_change_exit_isr = 0; /* * The state change occured, skip all * other interrupts */ goto isr_end; } } } /* * Test Fifo Error Interrupt * If set shutdown all interfaces and reconfigure */ if (bit_test((u_int8_t *)®, ERROR_INTR_ENABLE_BIT)) if (bit_test((u_int8_t *)®, ERROR_INTR_FLAG)) fifo_error_interrupt(card, reg); /* * Checking for Interrupt source: * 1. Receive DMA Engine * 2. Transmit DMA Engine * 3. Error conditions. */ if (bit_test((u_int8_t *)®, GLOBAL_INTR_ENABLE_BIT) && bit_test((u_int8_t *)®, DMA_INTR_FLAG)) { /* Receive DMA Engine */ sdla_bus_read_4(card->hw, XILINX_DMA_RX_INTR_PENDING_REG, &dma_rx_reg); dma_rx_reg &= card->u.xilinx.active_ch_map; if (dma_rx_reg == 0) goto isr_rx; for (i = 0; i < card->u.xilinx.num_of_time_slots; i++) { if (bit_test((u_int8_t *)&dma_rx_reg, i) && bit_test((u_int8_t *) &card->u.xilinx.logic_ch_map, i)) { sc = (xilinx_softc_t *) card->u.xilinx.dev_to_ch_map[i]; if (!sc) { log(LOG_INFO, "%s: Error: No Dev for " "Rx logical ch=%d\n", card->devname, i); continue; } xilinx_dma_rx_complete(card, sc); } } isr_rx: /* Transmit DMA Engine */ sdla_bus_read_4(card->hw, XILINX_DMA_TX_INTR_PENDING_REG, &dma_tx_reg); dma_tx_reg &= card->u.xilinx.active_ch_map; if (dma_tx_reg == 0) goto isr_tx; for (i = 0; i < card->u.xilinx.num_of_time_slots; i++) { if (bit_test((u_int8_t *)&dma_tx_reg, i) && bit_test((u_int8_t *) &card->u.xilinx.logic_ch_map, i)) { sc = (xilinx_softc_t *) card->u.xilinx.dev_to_ch_map[i]; if (!sc) { log(LOG_INFO, "%s: Error: No Dev for " "Tx logical ch=%d\n", card->devname, i); continue; } xilinx_dma_tx_complete(card, sc); } } } isr_tx: isr_end: /* write_cpld(card, LED_CONTROL_REG, 0x0E); */ bit_clear((u_int8_t *)&card->in_isr, 0); return; } /* * TASK Functions and Triggers */ /* * port_set_state * * Set PORT state. * */ static void port_set_state(sdla_t *card, int state) { wanpipe_common_t *common; if (card->state != state) { switch (state) { case WAN_CONNECTED: log(LOG_INFO, "%s: Link connected!\n", card->devname); aft_red_led_ctrl(card, AFT_LED_OFF); aft_green_led_ctrl(card, AFT_LED_ON); break; case WAN_CONNECTING: log(LOG_INFO, "%s: Link connecting...\n", card->devname); aft_red_led_ctrl(card, AFT_LED_ON); aft_green_led_ctrl(card, AFT_LED_OFF); break; case WAN_DISCONNECTED: log(LOG_INFO, "%s: Link disconnected!\n", card->devname); aft_red_led_ctrl(card, AFT_LED_ON); aft_green_led_ctrl(card, AFT_LED_OFF); break; } card->state = state; LIST_FOREACH(common, &card->dev_head, next) { struct ifnet *ifp = (struct ifnet *)&common->ifp; if (ifp) set_chan_state(card, ifp, state); } } } /* * handle_front_end_state */ static void handle_front_end_state(void *card_id) { sdla_t *card = (sdla_t *)card_id; if (card->front_end_status == FE_CONNECTED) { enable_data_error_intr(card); port_set_state(card, WAN_CONNECTED); card->u.xilinx.state_change_exit_isr = 1; } else { port_set_state(card, WAN_CONNECTING); disable_data_error_intr(card, LINK_DOWN); card->u.xilinx.state_change_exit_isr = 1; } } static unsigned char read_cpld(sdla_t *card, unsigned short cpld_off) { u_int16_t org_off; u_int8_t tmp; cpld_off &= ~BIT_DEV_ADDR_CLEAR; cpld_off |= BIT_DEV_ADDR_CPLD; /* Save the current address. */ sdla_bus_read_2(card->hw, XILINX_MCPU_INTERFACE_ADDR, &org_off); sdla_bus_write_2(card->hw, XILINX_MCPU_INTERFACE_ADDR, cpld_off); sdla_bus_read_1(card->hw, XILINX_MCPU_INTERFACE, &tmp); /* Restore original address */ sdla_bus_write_2(card->hw, XILINX_MCPU_INTERFACE_ADDR, org_off); return (tmp); } static unsigned char write_cpld(sdla_t *card, unsigned short off, unsigned char data) { u_int16_t org_off; off &= ~BIT_DEV_ADDR_CLEAR; off |= BIT_DEV_ADDR_CPLD; /* Save the current original address */ sdla_bus_read_2(card->hw, XILINX_MCPU_INTERFACE_ADDR, &org_off); sdla_bus_write_2(card->hw, XILINX_MCPU_INTERFACE_ADDR, off); /* This delay is required to avoid bridge optimization * (combining two writes together)*/ DELAY(5); sdla_bus_write_1(card->hw, XILINX_MCPU_INTERFACE, data); /* This delay is required to avoid bridge optimization * (combining two writes together)*/ DELAY(5); /* Restore the original address */ sdla_bus_write_2(card->hw, XILINX_MCPU_INTERFACE_ADDR, org_off); return (0); } static unsigned char write_front_end_reg(void *card1, unsigned short off, unsigned char value) { sdla_t *card = (sdla_t *)card1; off &= ~BIT_DEV_ADDR_CLEAR; sdla_bus_write_2(card->hw, XILINX_MCPU_INTERFACE_ADDR, off); /* * These delays are required to avoid bridge optimization * (combining two writes together) */ DELAY(5); sdla_bus_write_1(card->hw, XILINX_MCPU_INTERFACE, value); DELAY(5); return (0); } /* * Read TE1/56K Front end registers */ static unsigned char read_front_end_reg(void *card1, unsigned short off) { sdla_t* card = (sdla_t *)card1; u_int8_t tmp; off &= ~BIT_DEV_ADDR_CLEAR; sdla_bus_write_2(card->hw, XILINX_MCPU_INTERFACE_ADDR, off); sdla_bus_read_1(card->hw, XILINX_MCPU_INTERFACE, &tmp); DELAY(5); return (tmp); } /* * Run only after the front end comes up from down state. * * Clean the DMA Tx/Rx pending interrupts. * (Ignore since we will reconfigure * all dma descriptors. DMA controler * was already disabled on link down) * * For all channels clean Tx/Rx Fifo * * Enable DMA controler * (This starts the fifo cleaning * process) * * For all channels reprogram Tx/Rx DMA * descriptors. * * Clean the Tx/Rx Error pending interrupts. * (Since dma fifo's are now empty) * * Enable global DMA and Error interrutps. * */ static void enable_data_error_intr(sdla_t *card) { wanpipe_common_t *common; struct ifnet *ifp; u_int32_t reg; /* Clean Tx/Rx DMA interrupts */ sdla_bus_read_4(card->hw, XILINX_DMA_RX_INTR_PENDING_REG, ®); sdla_bus_read_4(card->hw, XILINX_DMA_TX_INTR_PENDING_REG, ®); /* For all channels clean Tx/Rx fifos */ LIST_FOREACH(common, &card->dev_head, next) { xilinx_softc_t *sc; ifp = (struct ifnet *)&common->ifp; if (!ifp || !ifp->if_softc) continue; sc = ifp->if_softc; #if 0 if (!(ifp->if_flags & IFF_UP)) continue; #endif #ifdef DEBUG_INIT log(LOG_INFO, "%s: Init interface fifo no wait %s\n", sc->if_name, __FUNCTION__); #endif xilinx_init_rx_dev_fifo(card, sc, WP_NO_WAIT); xilinx_init_tx_dev_fifo(card, sc, WP_NO_WAIT); } /* * Enable DMA controler, in order to start the * fifo cleaning */ sdla_bus_read_4(card->hw, XILINX_DMA_CONTROL_REG, ®); bit_set((u_int8_t *)®, DMA_ENGINE_ENABLE_BIT); sdla_bus_write_4(card->hw, XILINX_DMA_CONTROL_REG, reg); /* For all channels clean Tx/Rx fifos */ LIST_FOREACH(common, &card->dev_head, next) { xilinx_softc_t *sc; ifp = (struct ifnet *)&common->ifp; if (!ifp || ifp->if_softc == NULL) continue; sc = ifp->if_softc; #if 0 if (!(ifp->if_flags & IFF_UP)) continue; #endif #ifdef DEBUG_INIT log(LOG_INFO, "%s: Init interface fifo %s\n", sc->if_name, __FUNCTION__); #endif xilinx_init_rx_dev_fifo(card, sc, WP_WAIT); xilinx_init_tx_dev_fifo(card, sc, WP_WAIT); #ifdef DEBUG_INIT log(LOG_INFO, "%s: Clearing Fifo and idle_flag %s\n", card->devname, sc->if_name); #endif bit_clear((u_int8_t *)&sc->idle_start, 0); } /* For all channels, reprogram Tx/Rx DMA descriptors. * For Tx also make sure that the BUSY flag is clear * and previoulsy Tx packet is deallocated */ LIST_FOREACH(common, &card->dev_head, next) { xilinx_softc_t *sc; ifp = (struct ifnet *)&common->ifp; if (!ifp || !ifp->if_softc) continue; sc = ifp->if_softc; #if 0 if (!(ifp->if_flags & IFF_UP)) { continue; } #endif #ifdef DEBUG_INIT log(LOG_INFO, "%s: Init interface %s\n", sc->if_name, __FUNCTION__); #endif if (sc->rx_dma_buf) { aft_reload_rx_dma_buff(sc, sc->rx_dma_buf); sc->rx_dma_buf = NULL; } xilinx_dma_rx(card, sc); if (sc->tx_dma_addr && sc->tx_dma_len) { sc->tx_dma_addr = 0; sc->tx_dma_len = 0; } if (sc->tx_dma_mbuf) { bus_dmamap_unload(sc->dmatag, sc->tx_dmamap); m_freem(sc->tx_dma_mbuf); sc->tx_dma_mbuf = NULL; } bit_clear((u_int8_t *)&sc->dma_status, TX_BUSY); bit_clear((u_int8_t *)&sc->idle_start, 0); #ifdef DEBUG_INIT log(LOG_INFO, "%s: Clearing Fifo and idle_flag %s\n", card->devname, sc->if_name); #endif } /* * Clean Tx/Rx Error interrupts, since fifos are now * empty, and Tx fifo may generate an underrun which * we want to ignore :) */ sdla_bus_read_4(card->hw, XILINX_HDLC_RX_INTR_PENDING_REG, ®); sdla_bus_read_4(card->hw, XILINX_HDLC_TX_INTR_PENDING_REG, ®); /* Enable Global DMA and Error Interrupts */ reg = 0; sdla_bus_read_4(card->hw, XILINX_CHIP_CFG_REG, ®); bit_set((u_int8_t *)®, GLOBAL_INTR_ENABLE_BIT); bit_set((u_int8_t *)®, ERROR_INTR_ENABLE_BIT); sdla_bus_write_4(card->hw, XILINX_CHIP_CFG_REG, reg); return; } static void disable_data_error_intr(sdla_t *card, unsigned char event) { u_int32_t reg; sdla_bus_read_4(card->hw, XILINX_CHIP_CFG_REG, ®); bit_clear((u_int8_t *)®, GLOBAL_INTR_ENABLE_BIT); bit_clear((u_int8_t *)®, ERROR_INTR_ENABLE_BIT); if (event == DEVICE_DOWN) bit_clear((u_int8_t *)®, FRONT_END_INTR_ENABLE_BIT); sdla_bus_write_4(card->hw, XILINX_CHIP_CFG_REG, reg); sdla_bus_read_4(card->hw, XILINX_DMA_CONTROL_REG, ®); bit_clear((u_int8_t *)®, DMA_ENGINE_ENABLE_BIT); sdla_bus_write_4(card->hw, XILINX_DMA_CONTROL_REG, reg); } static void xilinx_init_tx_dma_descr(sdla_t *card, xilinx_softc_t *sc) { unsigned long dma_descr; unsigned long reg = 0; dma_descr = (sc->logic_ch_num << 4) + XILINX_TxDMA_DESCRIPTOR_HI; sdla_bus_write_4(card->hw, dma_descr, reg); } static void xilinx_tx_fifo_under_recover(sdla_t *card, xilinx_softc_t *sc) { struct ifnet *ifp = (struct ifnet *)&sc->common.ifp; u_int32_t reg = 0; unsigned long dma_descr; #ifdef DEBUG_ERR log(LOG_INFO, "%s:%s: Tx Fifo Recovery \n", card->devname, sc->if_name); #endif /* Initialize Tx DMA descriptor: Stop DMA */ dma_descr = (sc->logic_ch_num << 4) + XILINX_TxDMA_DESCRIPTOR_HI; sdla_bus_write_4(card->hw, dma_descr, reg); /* Clean the TX FIFO */ xilinx_init_tx_dev_fifo(card, sc, WP_WAIT); if (sc->tx_dma_addr && sc->tx_dma_len) { sc->tx_dma_addr = 0; sc->tx_dma_len = 0; } /* Requeue the current tx packet, for re-transmission */ if (sc->tx_dma_mbuf) { IF_PREPEND(&sc->wp_tx_pending_list, (struct mbuf *)sc->tx_dma_mbuf); sc->tx_dma_mbuf = NULL; } /* * Wake up the stack, because tx dma interrupt failed */ if (ifp) ifp->if_oerrors++; #ifdef DEBUG_ERR log(LOG_INFO, "%s:%s: Tx Fifo Recovery: Restarting Transmission \n", card->devname, sc->if_name); #endif /* Re-start transmission */ bit_clear((u_int8_t *)&sc->dma_status, TX_BUSY); if (!xilinx_dma_tx(card, sc)) { /* If we was able to transmit and the interface is set * to OACTIVE remove this flag and let kernel try to * transmit. */ if (ifp->if_flags & IFF_OACTIVE) ifp->if_flags &= ~IFF_OACTIVE; } return; } static int xilinx_write_ctrl_hdlc(sdla_t *card, u_int32_t timeslot, u_int8_t reg_off, u_int32_t data) { u_int32_t reg; u_int32_t ts_orig = timeslot; unsigned long timeout = ticks; if (timeslot == 0) timeslot = card->u.xilinx.num_of_time_slots - 2; else if (timeslot == 1) timeslot = card->u.xilinx.num_of_time_slots - 1; else timeslot -= 2; timeslot = timeslot << XILINX_CURRENT_TIMESLOT_SHIFT; timeslot &= XILINX_CURRENT_TIMESLOT_MASK; for (;;) { sdla_bus_read_4(card->hw, XILINX_TIMESLOT_HDLC_CHAN_REG, ®); reg &= XILINX_CURRENT_TIMESLOT_MASK; if (reg == timeslot) { sdla_bus_write_4(card->hw, reg_off, data); return (0); } if ((ticks-timeout) > 1) { log(LOG_INFO, "%s: Error: Access to timeslot %d " "timed out!\n", card->devname, ts_orig); return (EIO); } } return (EIO); } static int set_chan_state(sdla_t *card, struct ifnet *ifp, int state) { xilinx_softc_t *sc = ifp->if_softc; if (sc == NULL) return (0); if (state == WAN_CONNECTED) { #ifdef DEBUG_INIT log(LOG_INFO, "%s: Setting idle_start to 0\n", sc->if_name); #endif bit_clear((u_int8_t *)&sc->idle_start, 0); sc->common.ifp.pp_up(&sc->common.ifp); } else if (state == WAN_DISCONNECTED) sc->common.ifp.pp_down(&sc->common.ifp); return (0); } static char fifo_size_vector[] = {1, 2, 4, 8, 16, 32}; static char fifo_code_vector[] = {0, 1, 3, 7, 0xF, 0x1F}; static int request_fifo_baddr_and_size(sdla_t *card, xilinx_softc_t *sc) { unsigned char req_fifo_size, fifo_size; int i; /* * Calculate the optimal fifo size based * on the number of time slots requested */ if (IS_T1(&card->fe_te.te_cfg)) { if (sc->num_of_time_slots == NUM_OF_T1_CHANNELS) req_fifo_size = 32; else if (sc->num_of_time_slots == 1) req_fifo_size = 1; else if (sc->num_of_time_slots == 2 || sc->num_of_time_slots == 3) req_fifo_size = 2; else if (sc->num_of_time_slots >= 4 && sc->num_of_time_slots <= 7) req_fifo_size = 4; else if (sc->num_of_time_slots >= 8 && sc->num_of_time_slots <= 15) req_fifo_size = 8; else if (sc->num_of_time_slots >= 16 && sc->num_of_time_slots <= 23) req_fifo_size = 16; else { log(LOG_INFO, "%s: Invalid number of timeslots %d\n", card->devname, sc->num_of_time_slots); return (EINVAL); } } else { if (sc->num_of_time_slots == (NUM_OF_E1_CHANNELS-1)) req_fifo_size = 32; else if (sc->num_of_time_slots == 1) req_fifo_size = 1; else if (sc->num_of_time_slots == 2 || sc->num_of_time_slots == 3) req_fifo_size = 2; else if (sc->num_of_time_slots >= 4 && sc->num_of_time_slots <= 7) req_fifo_size = 4; else if (sc->num_of_time_slots >= 8 && sc->num_of_time_slots <= 15) req_fifo_size = 8; else if (sc->num_of_time_slots >= 16 && sc->num_of_time_slots <= 31) req_fifo_size = 16; else { log(LOG_INFO, "%s:%s: Invalid number of timeslots %d\n", card->devname, sc->if_name, sc->num_of_time_slots); return (EINVAL); } } #ifdef DEBUG_INIT log(LOG_INFO, "%s:%s: Optimal Fifo Size =%d Timeslots=%d \n", card->devname, sc->if_name, req_fifo_size, sc->num_of_time_slots); #endif fifo_size = map_fifo_baddr_and_size(card, req_fifo_size, &sc->fifo_base_addr); if (fifo_size == 0 || sc->fifo_base_addr == 31) { log(LOG_INFO, "%s:%s: Error: Failed to obtain fifo size %d " "or addr %d\n", card->devname, sc->if_name, fifo_size, sc->fifo_base_addr); return (EINVAL); } #ifdef DEBUG_INIT log(LOG_INFO, "%s:%s: Optimal Fifo Size =%d TS=%d New Fifo Size=%d\n", card->devname, sc->if_name, req_fifo_size, sc->num_of_time_slots, fifo_size); #endif for (i = 0; i < sizeof(fifo_size_vector); i++) { if (fifo_size_vector[i] == fifo_size) { sc->fifo_size_code = fifo_code_vector[i]; break; } } if (fifo_size != req_fifo_size) log(LOG_INFO, "%s:%s: WARN: Failed to obtain the req " "fifo %d got %d\n", card->devname, sc->if_name, req_fifo_size, fifo_size); #ifdef DEBUG_INIT log(LOG_INFO, "%s: %s:Fifo Size=%d TS=%d Fifo Code=%d Addr=%d\n", card->devname, sc->if_name, fifo_size, sc->num_of_time_slots, sc->fifo_size_code, sc->fifo_base_addr); #endif sc->fifo_size = fifo_size; return (0); } static int map_fifo_baddr_and_size(sdla_t *card, unsigned char fifo_size, unsigned char *addr) { u_int32_t reg = 0; int i; for (i = 0; i < fifo_size; i++) bit_set((u_int8_t *)®, i); #ifdef DEBUG_INIT log(LOG_INFO, "%s: Trying to MAP 0x%X to 0x%lX\n", card->devname, reg, card->u.xilinx.fifo_addr_map); #endif for (i = 0; i < 32; i += fifo_size) { if (card->u.xilinx.fifo_addr_map & (reg << i)) continue; card->u.xilinx.fifo_addr_map |= reg << i; *addr = i; #ifdef DEBUG_INIT log(LOG_INFO, "%s: Card fifo Map 0x%lX Addr =%d\n", card->devname, card->u.xilinx.fifo_addr_map, i); #endif return (fifo_size); } if (fifo_size == 1) return (0); fifo_size = fifo_size >> 1; return map_fifo_baddr_and_size(card, fifo_size, addr); } static int free_fifo_baddr_and_size(sdla_t *card, xilinx_softc_t *sc) { u_int32_t reg = 0; int i; for (i = 0; i < sc->fifo_size; i++) bit_set((u_int8_t *)®, i); #ifdef DEBUG_INIT log(LOG_INFO, "%s: Unmapping 0x%X from 0x%lX\n", card->devname, reg << sc->fifo_base_addr, card->u.xilinx.fifo_addr_map); #endif card->u.xilinx.fifo_addr_map &= ~(reg << sc->fifo_base_addr); #ifdef DEBUG_INIT log(LOG_INFO, "%s: New Map is 0x%lX\n", card->devname, card->u.xilinx.fifo_addr_map); #endif sc->fifo_size = 0; sc->fifo_base_addr = 0; return (0); } static void aft_red_led_ctrl(sdla_t *card, int mode) { unsigned int led; sdla_bus_read_4(card->hw, XILINX_CHIP_CFG_REG, &led); if (mode == AFT_LED_ON) bit_clear((u_int8_t *)&led, XILINX_RED_LED); else if (mode == AFT_LED_OFF) bit_set((u_int8_t *)&led, XILINX_RED_LED); else { if (bit_test((u_int8_t *)&led, XILINX_RED_LED)) bit_clear((u_int8_t *)&led, XILINX_RED_LED); else bit_set((u_int8_t *)&led, XILINX_RED_LED); } sdla_bus_write_4(card->hw, XILINX_CHIP_CFG_REG, led); } static void aft_led_timer(void *data) { sdla_t *card=(sdla_t *)data; unsigned int te_alarm; if (bit_test((u_int8_t *)&card->critical, CARD_DOWN)) return; if (IS_TE1(&card->fe_te.te_cfg)) { int s = splnet(); te_alarm = sdla_te_alarm(card, 0); te_alarm &= ~(BIT_OOSMF_ALARM|BIT_OOCMF_ALARM); if (!te_alarm) { if (card->state == WAN_CONNECTED) { aft_red_led_ctrl(card, AFT_LED_OFF); aft_green_led_ctrl(card, AFT_LED_ON); } else { aft_red_led_ctrl(card, AFT_LED_OFF); aft_green_led_ctrl(card, AFT_LED_TOGGLE); } } else if (te_alarm & (BIT_RED_ALARM|BIT_LOS_ALARM)) { /* Red or LOS Alarm solid RED */ aft_red_led_ctrl(card, AFT_LED_ON); aft_green_led_ctrl(card, AFT_LED_OFF); } else if (te_alarm & BIT_OOF_ALARM) { /* OOF Alarm flashing RED */ aft_red_led_ctrl(card, AFT_LED_TOGGLE); aft_green_led_ctrl(card, AFT_LED_OFF); } else if (te_alarm & BIT_AIS_ALARM) { /* AIS - Blue Alarm flasing RED and GREEN */ aft_red_led_ctrl(card, AFT_LED_TOGGLE); aft_green_led_ctrl(card, AFT_LED_TOGGLE); } else if (te_alarm & BIT_YEL_ALARM) { /* Yellow Alarm */ aft_red_led_ctrl(card, AFT_LED_ON); aft_green_led_ctrl(card, AFT_LED_ON); } else { /* Default case shouldn't happen */ log(LOG_INFO, "%s: Unknown Alarm 0x%X\n", card->devname, te_alarm); aft_red_led_ctrl(card, AFT_LED_ON); aft_green_led_ctrl(card, AFT_LED_ON); } splx(s); timeout_add_sec(&card->u.xilinx.led_timer, 1); } } int aft_core_ready(sdla_t *card) { u_int32_t reg; volatile unsigned char cnt = 0; for (;;) { sdla_bus_read_4(card->hw, XILINX_CHIP_CFG_REG, ®); if (!bit_test((u_int8_t *)®, HDLC_CORE_READY_FLAG_BIT)) { /* The HDLC Core is not ready! we have ** an error. */ if (++cnt > 5) return (EINVAL); else DELAY(500); /* WARNING: we cannot do this while in * critical area */ } else return (0); } return (EINVAL); }