/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #include #include #include uint32_t hxge_reclaim_pending = TXDMA_RECLAIM_PENDING_DEFAULT; uint32_t hxge_tx_minfree = 32; uint32_t hxge_tx_intr_thres = 0; uint32_t hxge_tx_max_gathers = TX_MAX_GATHER_POINTERS; uint32_t hxge_tx_tiny_pack = 1; uint32_t hxge_tx_use_bcopy = 1; extern uint32_t hxge_tx_ring_size; extern uint32_t hxge_bcopy_thresh; extern uint32_t hxge_dvma_thresh; extern uint32_t hxge_dma_stream_thresh; extern dma_method_t hxge_force_dma; /* Device register access attributes for PIO. */ extern ddi_device_acc_attr_t hxge_dev_reg_acc_attr; /* Device descriptor access attributes for DMA. */ extern ddi_device_acc_attr_t hxge_dev_desc_dma_acc_attr; /* Device buffer access attributes for DMA. */ extern ddi_device_acc_attr_t hxge_dev_buf_dma_acc_attr; extern ddi_dma_attr_t hxge_desc_dma_attr; extern ddi_dma_attr_t hxge_tx_dma_attr; static hxge_status_t hxge_map_txdma(p_hxge_t hxgep); static void hxge_unmap_txdma(p_hxge_t hxgep); static hxge_status_t hxge_txdma_hw_start(p_hxge_t hxgep); static void hxge_txdma_hw_stop(p_hxge_t hxgep); static hxge_status_t hxge_map_txdma_channel(p_hxge_t hxgep, uint16_t channel, p_hxge_dma_common_t *dma_buf_p, p_tx_ring_t *tx_desc_p, uint32_t num_chunks, p_hxge_dma_common_t *dma_cntl_p, p_tx_mbox_t *tx_mbox_p); static void hxge_unmap_txdma_channel(p_hxge_t hxgep, uint16_t channel, p_tx_ring_t tx_ring_p, p_tx_mbox_t tx_mbox_p); static hxge_status_t hxge_map_txdma_channel_buf_ring(p_hxge_t hxgep, uint16_t, p_hxge_dma_common_t *, p_tx_ring_t *, uint32_t); static void hxge_unmap_txdma_channel_buf_ring(p_hxge_t hxgep, p_tx_ring_t tx_ring_p); static void hxge_map_txdma_channel_cfg_ring(p_hxge_t, uint16_t, p_hxge_dma_common_t *, p_tx_ring_t, p_tx_mbox_t *); static void hxge_unmap_txdma_channel_cfg_ring(p_hxge_t hxgep, p_tx_ring_t tx_ring_p, p_tx_mbox_t tx_mbox_p); static hxge_status_t hxge_txdma_start_channel(p_hxge_t hxgep, uint16_t channel, p_tx_ring_t tx_ring_p, p_tx_mbox_t tx_mbox_p); static hxge_status_t hxge_txdma_stop_channel(p_hxge_t hxgep, uint16_t channel, p_tx_ring_t tx_ring_p, p_tx_mbox_t tx_mbox_p); static p_tx_ring_t hxge_txdma_get_ring(p_hxge_t hxgep, uint16_t channel); static hxge_status_t hxge_tx_err_evnts(p_hxge_t hxgep, uint_t index, p_hxge_ldv_t ldvp, tdc_stat_t cs); static p_tx_mbox_t hxge_txdma_get_mbox(p_hxge_t hxgep, uint16_t channel); static hxge_status_t hxge_txdma_fatal_err_recover(p_hxge_t hxgep, uint16_t channel, p_tx_ring_t tx_ring_p); static hxge_status_t hxge_tx_port_fatal_err_recover(p_hxge_t hxgep); hxge_status_t hxge_init_txdma_channels(p_hxge_t hxgep) { hxge_status_t status = HXGE_OK; block_reset_t reset_reg; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_init_txdma_channels")); /* * Reset TDC block from PEU to cleanup any unknown configuration. * This may be resulted from previous reboot. */ reset_reg.value = 0; reset_reg.bits.tdc_rst = 1; HXGE_REG_WR32(hxgep->hpi_handle, BLOCK_RESET, reset_reg.value); HXGE_DELAY(1000); status = hxge_map_txdma(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "<== hxge_init_txdma_channels: status 0x%x", status)); return (status); } status = hxge_txdma_hw_start(hxgep); if (status != HXGE_OK) { hxge_unmap_txdma(hxgep); return (status); } HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_init_txdma_channels: status 0x%x", status)); return (HXGE_OK); } void hxge_uninit_txdma_channels(p_hxge_t hxgep) { HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_uninit_txdma_channels")); hxge_txdma_hw_stop(hxgep); hxge_unmap_txdma(hxgep); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_uinit_txdma_channels")); } void hxge_setup_dma_common(p_hxge_dma_common_t dest_p, p_hxge_dma_common_t src_p, uint32_t entries, uint32_t size) { size_t tsize; *dest_p = *src_p; tsize = size * entries; dest_p->alength = tsize; dest_p->nblocks = entries; dest_p->block_size = size; dest_p->offset += tsize; src_p->kaddrp = (caddr_t)dest_p->kaddrp + tsize; src_p->alength -= tsize; src_p->dma_cookie.dmac_laddress += tsize; src_p->dma_cookie.dmac_size -= tsize; } hxge_status_t hxge_reset_txdma_channel(p_hxge_t hxgep, uint16_t channel, uint64_t reg_data) { hpi_status_t rs = HPI_SUCCESS; hxge_status_t status = HXGE_OK; hpi_handle_t handle; HXGE_DEBUG_MSG((hxgep, TX_CTL, " ==> hxge_reset_txdma_channel")); handle = HXGE_DEV_HPI_HANDLE(hxgep); if ((reg_data & TDC_TDR_RST_MASK) == TDC_TDR_RST_MASK) { rs = hpi_txdma_channel_reset(handle, channel); } else { rs = hpi_txdma_channel_control(handle, TXDMA_RESET, channel); } if (rs != HPI_SUCCESS) { status = HXGE_ERROR | rs; } /* * Reset the tail (kick) register to 0. (Hardware will not reset it. Tx * overflow fatal error if tail is not set to 0 after reset! */ TXDMA_REG_WRITE64(handle, TDC_TDR_KICK, channel, 0); HXGE_DEBUG_MSG((hxgep, TX_CTL, " <== hxge_reset_txdma_channel")); return (status); } hxge_status_t hxge_init_txdma_channel_event_mask(p_hxge_t hxgep, uint16_t channel, tdc_int_mask_t *mask_p) { hpi_handle_t handle; hpi_status_t rs = HPI_SUCCESS; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_init_txdma_channel_event_mask")); handle = HXGE_DEV_HPI_HANDLE(hxgep); /* * Mask off tx_rng_oflow since it is a false alarm. The driver * ensures not over flowing the hardware and check the hardware * status. */ mask_p->bits.tx_rng_oflow = 1; rs = hpi_txdma_event_mask(handle, OP_SET, channel, mask_p); if (rs != HPI_SUCCESS) { status = HXGE_ERROR | rs; } HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_init_txdma_channel_event_mask")); return (status); } hxge_status_t hxge_enable_txdma_channel(p_hxge_t hxgep, uint16_t channel, p_tx_ring_t tx_desc_p, p_tx_mbox_t mbox_p) { hpi_handle_t handle; hpi_status_t rs = HPI_SUCCESS; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_enable_txdma_channel")); handle = HXGE_DEV_HPI_HANDLE(hxgep); /* * Use configuration data composed at init time. Write to hardware the * transmit ring configurations. */ rs = hpi_txdma_ring_config(handle, OP_SET, channel, (uint64_t *)&(tx_desc_p->tx_ring_cfig.value)); if (rs != HPI_SUCCESS) { return (HXGE_ERROR | rs); } /* Write to hardware the mailbox */ rs = hpi_txdma_mbox_config(handle, OP_SET, channel, (uint64_t *)&mbox_p->tx_mbox.dma_cookie.dmac_laddress); if (rs != HPI_SUCCESS) { return (HXGE_ERROR | rs); } /* Start the DMA engine. */ rs = hpi_txdma_channel_init_enable(handle, channel); if (rs != HPI_SUCCESS) { return (HXGE_ERROR | rs); } HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_enable_txdma_channel")); return (status); } void hxge_fill_tx_hdr(p_mblk_t mp, boolean_t fill_len, boolean_t l4_cksum, int pkt_len, uint8_t npads, p_tx_pkt_hdr_all_t pkthdrp) { p_tx_pkt_header_t hdrp; p_mblk_t nmp; uint64_t tmp; size_t mblk_len; size_t iph_len; size_t hdrs_size; uint8_t *ip_buf; uint16_t eth_type; uint8_t ipproto; boolean_t is_vlan = B_FALSE; size_t eth_hdr_size; uint8_t hdrs_buf[sizeof (struct ether_header) + 64 + sizeof (uint32_t)]; HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_fill_tx_hdr: mp $%p", mp)); /* * Caller should zero out the headers first. */ hdrp = (p_tx_pkt_header_t)&pkthdrp->pkthdr; if (fill_len) { HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_fill_tx_hdr: pkt_len %d npads %d", pkt_len, npads)); tmp = (uint64_t)pkt_len; hdrp->value |= (tmp << TX_PKT_HEADER_TOT_XFER_LEN_SHIFT); goto fill_tx_header_done; } tmp = (uint64_t)npads; hdrp->value |= (tmp << TX_PKT_HEADER_PAD_SHIFT); /* * mp is the original data packet (does not include the Neptune * transmit header). */ nmp = mp; mblk_len = (size_t)nmp->b_wptr - (size_t)nmp->b_rptr; HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_fill_tx_hdr: mp $%p b_rptr $%p len %d", mp, nmp->b_rptr, mblk_len)); ip_buf = NULL; bcopy(nmp->b_rptr, &hdrs_buf[0], sizeof (struct ether_vlan_header)); eth_type = ntohs(((p_ether_header_t)hdrs_buf)->ether_type); HXGE_DEBUG_MSG((NULL, TX_CTL, "==> : hxge_fill_tx_hdr: (value 0x%llx) ether type 0x%x", eth_type, hdrp->value)); if (eth_type < ETHERMTU) { tmp = 1ull; hdrp->value |= (tmp << TX_PKT_HEADER_LLC_SHIFT); HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_hdr_init: LLC value 0x%llx", hdrp->value)); if (*(hdrs_buf + sizeof (struct ether_header)) == LLC_SNAP_SAP) { eth_type = ntohs(*((uint16_t *)(hdrs_buf + sizeof (struct ether_header) + 6))); HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_hdr_init: LLC ether type 0x%x", eth_type)); } else { goto fill_tx_header_done; } } else if (eth_type == VLAN_ETHERTYPE) { tmp = 1ull; hdrp->value |= (tmp << TX_PKT_HEADER_VLAN__SHIFT); eth_type = ntohs(((struct ether_vlan_header *) hdrs_buf)->ether_type); is_vlan = B_TRUE; HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_hdr_init: VLAN value 0x%llx", hdrp->value)); } if (!is_vlan) { eth_hdr_size = sizeof (struct ether_header); } else { eth_hdr_size = sizeof (struct ether_vlan_header); } switch (eth_type) { case ETHERTYPE_IP: if (mblk_len > eth_hdr_size + sizeof (uint8_t)) { ip_buf = nmp->b_rptr + eth_hdr_size; mblk_len -= eth_hdr_size; iph_len = ((*ip_buf) & 0x0f); if (mblk_len > (iph_len + sizeof (uint32_t))) { ip_buf = nmp->b_rptr; ip_buf += eth_hdr_size; } else { ip_buf = NULL; } } if (ip_buf == NULL) { hdrs_size = 0; ((p_ether_header_t)hdrs_buf)->ether_type = 0; while ((nmp) && (hdrs_size < sizeof (hdrs_buf))) { mblk_len = (size_t)nmp->b_wptr - (size_t)nmp->b_rptr; if (mblk_len >= (sizeof (hdrs_buf) - hdrs_size)) mblk_len = sizeof (hdrs_buf) - hdrs_size; bcopy(nmp->b_rptr, &hdrs_buf[hdrs_size], mblk_len); hdrs_size += mblk_len; nmp = nmp->b_cont; } ip_buf = hdrs_buf; ip_buf += eth_hdr_size; iph_len = ((*ip_buf) & 0x0f); } ipproto = ip_buf[9]; tmp = (uint64_t)iph_len; hdrp->value |= (tmp << TX_PKT_HEADER_IHL_SHIFT); tmp = (uint64_t)(eth_hdr_size >> 1); hdrp->value |= (tmp << TX_PKT_HEADER_L3START_SHIFT); HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_fill_tx_hdr: IPv4 " " iph_len %d l3start %d eth_hdr_size %d proto 0x%x" "tmp 0x%x", iph_len, hdrp->bits.l3start, eth_hdr_size, ipproto, tmp)); HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_hdr_init: IP value 0x%llx", hdrp->value)); break; case ETHERTYPE_IPV6: hdrs_size = 0; ((p_ether_header_t)hdrs_buf)->ether_type = 0; while ((nmp) && (hdrs_size < sizeof (hdrs_buf))) { mblk_len = (size_t)nmp->b_wptr - (size_t)nmp->b_rptr; if (mblk_len >= (sizeof (hdrs_buf) - hdrs_size)) mblk_len = sizeof (hdrs_buf) - hdrs_size; bcopy(nmp->b_rptr, &hdrs_buf[hdrs_size], mblk_len); hdrs_size += mblk_len; nmp = nmp->b_cont; } ip_buf = hdrs_buf; ip_buf += eth_hdr_size; tmp = 1ull; hdrp->value |= (tmp << TX_PKT_HEADER_IP_VER_SHIFT); tmp = (eth_hdr_size >> 1); hdrp->value |= (tmp << TX_PKT_HEADER_L3START_SHIFT); /* byte 6 is the next header protocol */ ipproto = ip_buf[6]; HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_fill_tx_hdr: IPv6 " " iph_len %d l3start %d eth_hdr_size %d proto 0x%x", iph_len, hdrp->bits.l3start, eth_hdr_size, ipproto)); HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_hdr_init: IPv6 " "value 0x%llx", hdrp->value)); break; default: HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_fill_tx_hdr: non-IP")); goto fill_tx_header_done; } switch (ipproto) { case IPPROTO_TCP: HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_fill_tx_hdr: TCP (cksum flag %d)", l4_cksum)); if (l4_cksum) { tmp = 1ull; hdrp->value |= (tmp << TX_PKT_HEADER_PKT_TYPE_SHIFT); HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_hdr_init: TCP CKSUM" "value 0x%llx", hdrp->value)); } HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_hdr_init: TCP value 0x%llx", hdrp->value)); break; case IPPROTO_UDP: HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_fill_tx_hdr: UDP")); if (l4_cksum) { tmp = 0x2ull; hdrp->value |= (tmp << TX_PKT_HEADER_PKT_TYPE_SHIFT); } HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_hdr_init: UDP value 0x%llx", hdrp->value)); break; default: goto fill_tx_header_done; } fill_tx_header_done: HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_fill_tx_hdr: pkt_len %d npads %d value 0x%llx", pkt_len, npads, hdrp->value)); HXGE_DEBUG_MSG((NULL, TX_CTL, "<== hxge_fill_tx_hdr")); } /*ARGSUSED*/ p_mblk_t hxge_tx_pkt_header_reserve(p_mblk_t mp, uint8_t *npads) { p_mblk_t newmp = NULL; if ((newmp = allocb(TX_PKT_HEADER_SIZE, BPRI_MED)) == NULL) { HXGE_DEBUG_MSG((NULL, TX_CTL, "<== hxge_tx_pkt_header_reserve: allocb failed")); return (NULL); } HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_header_reserve: get new mp")); DB_TYPE(newmp) = M_DATA; newmp->b_rptr = newmp->b_wptr = DB_LIM(newmp); linkb(newmp, mp); newmp->b_rptr -= TX_PKT_HEADER_SIZE; HXGE_DEBUG_MSG((NULL, TX_CTL, "==>hxge_tx_pkt_header_reserve: b_rptr $%p b_wptr $%p", newmp->b_rptr, newmp->b_wptr)); HXGE_DEBUG_MSG((NULL, TX_CTL, "<== hxge_tx_pkt_header_reserve: use new mp")); return (newmp); } int hxge_tx_pkt_nmblocks(p_mblk_t mp, int *tot_xfer_len_p) { uint_t nmblks; ssize_t len; uint_t pkt_len; p_mblk_t nmp, bmp, tmp; uint8_t *b_wptr; HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_nmblocks: mp $%p rptr $%p wptr $%p len %d", mp, mp->b_rptr, mp->b_wptr, MBLKL(mp))); nmp = mp; bmp = mp; nmblks = 0; pkt_len = 0; *tot_xfer_len_p = 0; while (nmp) { len = MBLKL(nmp); HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_nmblocks: " "len %d pkt_len %d nmblks %d tot_xfer_len %d", len, pkt_len, nmblks, *tot_xfer_len_p)); if (len <= 0) { bmp = nmp; nmp = nmp->b_cont; HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_nmblocks:" " len (0) pkt_len %d nmblks %d", pkt_len, nmblks)); continue; } *tot_xfer_len_p += len; HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_nmblocks: " "len %d pkt_len %d nmblks %d tot_xfer_len %d", len, pkt_len, nmblks, *tot_xfer_len_p)); if (len < hxge_bcopy_thresh) { HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_nmblocks: " "len %d (< thresh) pkt_len %d nmblks %d", len, pkt_len, nmblks)); if (pkt_len == 0) nmblks++; pkt_len += len; if (pkt_len >= hxge_bcopy_thresh) { pkt_len = 0; len = 0; nmp = bmp; } } else { HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_nmblocks: " "len %d (> thresh) pkt_len %d nmblks %d", len, pkt_len, nmblks)); pkt_len = 0; nmblks++; /* * Hardware limits the transfer length to 4K. If len is * more than 4K, we need to break it up to at most 2 * more blocks. */ if (len > TX_MAX_TRANSFER_LENGTH) { uint32_t nsegs; HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_nmblocks: " "len %d pkt_len %d nmblks %d nsegs %d", len, pkt_len, nmblks, nsegs)); nsegs = 1; if (len % (TX_MAX_TRANSFER_LENGTH * 2)) { ++nsegs; } do { b_wptr = nmp->b_rptr + TX_MAX_TRANSFER_LENGTH; nmp->b_wptr = b_wptr; if ((tmp = dupb(nmp)) == NULL) { return (0); } tmp->b_rptr = b_wptr; tmp->b_wptr = nmp->b_wptr; tmp->b_cont = nmp->b_cont; nmp->b_cont = tmp; nmblks++; if (--nsegs) { nmp = tmp; } } while (nsegs); nmp = tmp; } } /* * Hardware limits the transmit gather pointers to 15. */ if (nmp->b_cont && (nmblks + TX_GATHER_POINTERS_THRESHOLD) > TX_MAX_GATHER_POINTERS) { HXGE_DEBUG_MSG((NULL, TX_CTL, "==> hxge_tx_pkt_nmblocks: pull msg - " "len %d pkt_len %d nmblks %d", len, pkt_len, nmblks)); /* Pull all message blocks from b_cont */ if ((tmp = msgpullup(nmp->b_cont, -1)) == NULL) { return (0); } freemsg(nmp->b_cont); nmp->b_cont = tmp; pkt_len = 0; } bmp = nmp; nmp = nmp->b_cont; } HXGE_DEBUG_MSG((NULL, TX_CTL, "<== hxge_tx_pkt_nmblocks: rptr $%p wptr $%p " "nmblks %d len %d tot_xfer_len %d", mp->b_rptr, mp->b_wptr, nmblks, MBLKL(mp), *tot_xfer_len_p)); return (nmblks); } boolean_t hxge_txdma_reclaim(p_hxge_t hxgep, p_tx_ring_t tx_ring_p, int nmblks) { boolean_t status = B_TRUE; p_hxge_dma_common_t tx_desc_dma_p; hxge_dma_common_t desc_area; p_tx_desc_t tx_desc_ring_vp; p_tx_desc_t tx_desc_p; p_tx_desc_t tx_desc_pp; tx_desc_t r_tx_desc; p_tx_msg_t tx_msg_ring; p_tx_msg_t tx_msg_p; hpi_handle_t handle; tdc_tdr_head_t tx_head; uint32_t pkt_len; uint_t tx_rd_index; uint16_t head_index, tail_index; uint8_t tdc; boolean_t head_wrap, tail_wrap; p_hxge_tx_ring_stats_t tdc_stats; tdc_byte_cnt_t byte_cnt; tdc_tdr_qlen_t qlen; int rc; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim")); status = ((tx_ring_p->descs_pending < hxge_reclaim_pending) && (nmblks != 0)); HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: pending %d reclaim %d nmblks %d", tx_ring_p->descs_pending, hxge_reclaim_pending, nmblks)); if (!status) { tx_desc_dma_p = &tx_ring_p->tdc_desc; desc_area = tx_ring_p->tdc_desc; tx_desc_ring_vp = tx_desc_dma_p->kaddrp; tx_desc_ring_vp = (p_tx_desc_t)DMA_COMMON_VPTR(desc_area); tx_rd_index = tx_ring_p->rd_index; tx_desc_p = &tx_desc_ring_vp[tx_rd_index]; tx_msg_ring = tx_ring_p->tx_msg_ring; tx_msg_p = &tx_msg_ring[tx_rd_index]; tdc = tx_ring_p->tdc; tdc_stats = tx_ring_p->tdc_stats; if (tx_ring_p->descs_pending > tdc_stats->tx_max_pend) { tdc_stats->tx_max_pend = tx_ring_p->descs_pending; } tail_index = tx_ring_p->wr_index; tail_wrap = tx_ring_p->wr_index_wrap; /* * tdc_byte_cnt reg can be used to get bytes transmitted. It * includes padding too in case of runt packets. */ handle = HXGE_DEV_HPI_HANDLE(hxgep); TXDMA_REG_READ64(handle, TDC_BYTE_CNT, tdc, &byte_cnt.value); tdc_stats->obytes_with_pad += byte_cnt.bits.byte_count; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: tdc %d tx_rd_index %d " "tail_index %d tail_wrap %d tx_desc_p $%p ($%p) ", tdc, tx_rd_index, tail_index, tail_wrap, tx_desc_p, (*(uint64_t *)tx_desc_p))); /* * Read the hardware maintained transmit head and wrap around * bit. */ TXDMA_REG_READ64(handle, TDC_TDR_HEAD, tdc, &tx_head.value); head_index = tx_head.bits.head; head_wrap = tx_head.bits.wrap; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: " "tx_rd_index %d tail %d tail_wrap %d head %d wrap %d", tx_rd_index, tail_index, tail_wrap, head_index, head_wrap)); /* * For debug only. This can be used to verify the qlen and make * sure the hardware is wrapping the Tdr correctly. */ TXDMA_REG_READ64(handle, TDC_TDR_QLEN, tdc, &qlen.value); HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: tdr_qlen %d tdr_pref_qlen %d", qlen.bits.tdr_qlen, qlen.bits.tdr_pref_qlen)); if (head_index == tail_index) { if (TXDMA_RING_EMPTY(head_index, head_wrap, tail_index, tail_wrap) && (head_index == tx_rd_index)) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: EMPTY")); return (B_TRUE); } HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: Checking if ring full")); if (TXDMA_RING_FULL(head_index, head_wrap, tail_index, tail_wrap)) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: full")); return (B_FALSE); } } HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: tx_rd_index and head_index")); /* XXXX: limit the # of reclaims */ tx_desc_pp = &r_tx_desc; while ((tx_rd_index != head_index) && (tx_ring_p->descs_pending != 0)) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: Checking if pending")); HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: descs_pending %d ", tx_ring_p->descs_pending)); HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: " "(tx_rd_index %d head_index %d (tx_desc_p $%p)", tx_rd_index, head_index, tx_desc_p)); tx_desc_pp->value = tx_desc_p->value; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: " "(tx_rd_index %d head_index %d " "tx_desc_p $%p (desc value 0x%llx) ", tx_rd_index, head_index, tx_desc_pp, (*(uint64_t *)tx_desc_pp))); HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: dump desc:")); /* * tdc_byte_cnt reg can be used to get bytes * transmitted */ pkt_len = tx_desc_pp->bits.tr_len; tdc_stats->obytes += pkt_len; tdc_stats->opackets += tx_desc_pp->bits.sop; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: pkt_len %d " "tdc channel %d opackets %d", pkt_len, tdc, tdc_stats->opackets)); if (tx_msg_p->flags.dma_type == USE_DVMA) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "tx_desc_p = $%p tx_desc_pp = $%p " "index = %d", tx_desc_p, tx_desc_pp, tx_ring_p->rd_index)); (void) dvma_unload(tx_msg_p->dvma_handle, 0, -1); tx_msg_p->dvma_handle = NULL; if (tx_ring_p->dvma_wr_index == tx_ring_p->dvma_wrap_mask) { tx_ring_p->dvma_wr_index = 0; } else { tx_ring_p->dvma_wr_index++; } tx_ring_p->dvma_pending--; } else if (tx_msg_p->flags.dma_type == USE_DMA) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: USE DMA")); if (rc = ddi_dma_unbind_handle (tx_msg_p->dma_handle)) { cmn_err(CE_WARN, "hxge_reclaim: " "ddi_dma_unbind_handle " "failed. status %d", rc); } } HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_reclaim: count packets")); /* * count a chained packet only once. */ if (tx_msg_p->tx_message != NULL) { freemsg(tx_msg_p->tx_message); tx_msg_p->tx_message = NULL; } tx_msg_p->flags.dma_type = USE_NONE; tx_rd_index = tx_ring_p->rd_index; tx_rd_index = (tx_rd_index + 1) & tx_ring_p->tx_wrap_mask; tx_ring_p->rd_index = tx_rd_index; tx_ring_p->descs_pending--; tx_desc_p = &tx_desc_ring_vp[tx_rd_index]; tx_msg_p = &tx_msg_ring[tx_rd_index]; } status = (nmblks <= (tx_ring_p->tx_ring_size - tx_ring_p->descs_pending - TX_FULL_MARK)); if (status) { cas32((uint32_t *)&tx_ring_p->queueing, 1, 0); } } else { status = (nmblks <= (tx_ring_p->tx_ring_size - tx_ring_p->descs_pending - TX_FULL_MARK)); } HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_reclaim status = 0x%08x", status)); return (status); } uint_t hxge_tx_intr(caddr_t arg1, caddr_t arg2) { p_hxge_ldv_t ldvp = (p_hxge_ldv_t)arg1; p_hxge_t hxgep = (p_hxge_t)arg2; p_hxge_ldg_t ldgp; uint8_t channel; uint32_t vindex; hpi_handle_t handle; tdc_stat_t cs; p_tx_ring_t *tx_rings; p_tx_ring_t tx_ring_p; hpi_status_t rs = HPI_SUCCESS; uint_t serviced = DDI_INTR_UNCLAIMED; hxge_status_t status = HXGE_OK; if (ldvp == NULL) { HXGE_DEBUG_MSG((NULL, INT_CTL, "<== hxge_tx_intr: hxgep $%p ldvp $%p", hxgep, ldvp)); return (DDI_INTR_UNCLAIMED); } if (arg2 == NULL || (void *) ldvp->hxgep != arg2) { hxgep = ldvp->hxgep; } /* * If the interface is not started, just swallow the interrupt * and don't rearm the logical device. */ if (hxgep->hxge_mac_state != HXGE_MAC_STARTED) return (DDI_INTR_CLAIMED); HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_tx_intr: hxgep(arg2) $%p ldvp(arg1) $%p", hxgep, ldvp)); /* * This interrupt handler is for a specific transmit dma channel. */ handle = HXGE_DEV_HPI_HANDLE(hxgep); /* Get the control and status for this channel. */ channel = ldvp->channel; ldgp = ldvp->ldgp; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_tx_intr: hxgep $%p ldvp (ldvp) $%p channel %d", hxgep, ldvp, channel)); rs = hpi_txdma_control_status(handle, OP_GET, channel, &cs); vindex = ldvp->vdma_index; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_tx_intr:channel %d ring index %d status 0x%08x", channel, vindex, rs)); if (!rs && cs.bits.marked) { HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_tx_intr:channel %d ring index %d " "status 0x%08x (marked bit set)", channel, vindex, rs)); tx_rings = hxgep->tx_rings->rings; tx_ring_p = tx_rings[vindex]; HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_tx_intr:channel %d ring index %d " "status 0x%08x (marked bit set, calling reclaim)", channel, vindex, rs)); MUTEX_ENTER(&tx_ring_p->lock); (void) hxge_txdma_reclaim(hxgep, tx_rings[vindex], 0); MUTEX_EXIT(&tx_ring_p->lock); mac_tx_update(hxgep->mach); } /* * Process other transmit control and status. Check the ldv state. */ status = hxge_tx_err_evnts(hxgep, ldvp->vdma_index, ldvp, cs); /* Clear the error bits */ RXDMA_REG_WRITE64(handle, TDC_STAT, channel, cs.value); /* * Rearm this logical group if this is a single device group. */ if (ldgp->nldvs == 1) { HXGE_DEBUG_MSG((hxgep, INT_CTL, "==> hxge_tx_intr: rearm")); if (status == HXGE_OK) { (void) hpi_intr_ldg_mgmt_set(handle, ldgp->ldg, B_TRUE, ldgp->ldg_timer); } } HXGE_DEBUG_MSG((hxgep, INT_CTL, "<== hxge_tx_intr")); serviced = DDI_INTR_CLAIMED; return (serviced); } void hxge_txdma_stop(p_hxge_t hxgep) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_stop")); (void) hxge_tx_vmac_disable(hxgep); (void) hxge_txdma_hw_mode(hxgep, HXGE_DMA_STOP); HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_stop")); } hxge_status_t hxge_txdma_hw_mode(p_hxge_t hxgep, boolean_t enable) { int i, ndmas; uint16_t channel; p_tx_rings_t tx_rings; p_tx_ring_t *tx_desc_rings; hpi_handle_t handle; hpi_status_t rs = HPI_SUCCESS; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_mode: enable mode %d", enable)); if (!(hxgep->drv_state & STATE_HW_INITIALIZED)) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_mode: not initialized")); return (HXGE_ERROR); } tx_rings = hxgep->tx_rings; if (tx_rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hw_mode: NULL global ring pointer")); return (HXGE_ERROR); } tx_desc_rings = tx_rings->rings; if (tx_desc_rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hw_mode: NULL rings pointer")); return (HXGE_ERROR); } ndmas = tx_rings->ndmas; if (!ndmas) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "<== hxge_txdma_hw_mode: no dma channel allocated")); return (HXGE_ERROR); } HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_mode: " "tx_rings $%p tx_desc_rings $%p ndmas %d", tx_rings, tx_desc_rings, ndmas)); handle = HXGE_DEV_HPI_HANDLE(hxgep); for (i = 0; i < ndmas; i++) { if (tx_desc_rings[i] == NULL) { continue; } channel = tx_desc_rings[i]->tdc; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_mode: channel %d", channel)); if (enable) { rs = hpi_txdma_channel_enable(handle, channel); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_mode: channel %d (enable) " "rs 0x%x", channel, rs)); } else { /* * Stop the dma channel and waits for the stop done. If * the stop done bit is not set, then force an error so * TXC will stop. All channels bound to this port need * to be stopped and reset after injecting an interrupt * error. */ rs = hpi_txdma_channel_disable(handle, channel); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_mode: channel %d (disable) " "rs 0x%x", channel, rs)); } } status = ((rs == HPI_SUCCESS) ? HXGE_OK : HXGE_ERROR | rs); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_txdma_hw_mode: status 0x%x", status)); return (status); } void hxge_txdma_enable_channel(p_hxge_t hxgep, uint16_t channel) { hpi_handle_t handle; HXGE_DEBUG_MSG((hxgep, DMA_CTL, "==> hxge_txdma_enable_channel: channel %d", channel)); handle = HXGE_DEV_HPI_HANDLE(hxgep); /* enable the transmit dma channels */ (void) hpi_txdma_channel_enable(handle, channel); HXGE_DEBUG_MSG((hxgep, DMA_CTL, "<== hxge_txdma_enable_channel")); } void hxge_txdma_disable_channel(p_hxge_t hxgep, uint16_t channel) { hpi_handle_t handle; HXGE_DEBUG_MSG((hxgep, DMA_CTL, "==> hxge_txdma_disable_channel: channel %d", channel)); handle = HXGE_DEV_HPI_HANDLE(hxgep); /* stop the transmit dma channels */ (void) hpi_txdma_channel_disable(handle, channel); HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_disable_channel")); } int hxge_txdma_stop_inj_err(p_hxge_t hxgep, int channel) { hpi_handle_t handle; int status; hpi_status_t rs = HPI_SUCCESS; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_stop_inj_err")); /* * Stop the dma channel waits for the stop done. If the stop done bit * is not set, then create an error. */ handle = HXGE_DEV_HPI_HANDLE(hxgep); rs = hpi_txdma_channel_disable(handle, channel); status = ((rs == HPI_SUCCESS) ? HXGE_OK : HXGE_ERROR | rs); if (status == HXGE_OK) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_stop_inj_err (channel %d): " "stopped OK", channel)); return (status); } HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_txdma_stop_inj_err (channel): stop failed (0x%x) " " (injected error but still not stopped)", channel, rs)); HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_stop_inj_err")); return (status); } /*ARGSUSED*/ void hxge_fixup_txdma_rings(p_hxge_t hxgep) { int index, ndmas; uint16_t channel; p_tx_rings_t tx_rings; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_fixup_txdma_rings")); /* * For each transmit channel, reclaim each descriptor and free buffers. */ tx_rings = hxgep->tx_rings; if (tx_rings == NULL) { HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_fixup_txdma_rings: NULL ring pointer")); return; } ndmas = tx_rings->ndmas; if (!ndmas) { HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_fixup_txdma_rings: no channel allocated")); return; } if (tx_rings->rings == NULL) { HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_fixup_txdma_rings: NULL rings pointer")); return; } HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_fixup_txdma_rings: " "tx_rings $%p tx_desc_rings $%p ndmas %d", tx_rings, tx_rings->rings, ndmas)); for (index = 0; index < ndmas; index++) { channel = tx_rings->rings[index]->tdc; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_fixup_txdma_rings: channel %d", channel)); hxge_txdma_fixup_channel(hxgep, tx_rings->rings[index], channel); } HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_fixup_txdma_rings")); } /*ARGSUSED*/ void hxge_txdma_fix_channel(p_hxge_t hxgep, uint16_t channel) { p_tx_ring_t ring_p; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_fix_channel")); ring_p = hxge_txdma_get_ring(hxgep, channel); if (ring_p == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_fix_channel")); return; } if (ring_p->tdc != channel) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_fix_channel: channel not matched " "ring tdc %d passed channel", ring_p->tdc, channel)); return; } hxge_txdma_fixup_channel(hxgep, ring_p, channel); HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_fix_channel")); } /*ARGSUSED*/ void hxge_txdma_fixup_channel(p_hxge_t hxgep, p_tx_ring_t ring_p, uint16_t channel) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_fixup_channel")); if (ring_p == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_fixup_channel: NULL ring pointer")); return; } if (ring_p->tdc != channel) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_fixup_channel: channel not matched " "ring tdc %d passed channel", ring_p->tdc, channel)); return; } MUTEX_ENTER(&ring_p->lock); (void) hxge_txdma_reclaim(hxgep, ring_p, 0); ring_p->rd_index = 0; ring_p->wr_index = 0; ring_p->ring_head.value = 0; ring_p->ring_kick_tail.value = 0; ring_p->descs_pending = 0; MUTEX_EXIT(&ring_p->lock); HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_fixup_channel")); } /*ARGSUSED*/ void hxge_txdma_hw_kick(p_hxge_t hxgep) { int index, ndmas; uint16_t channel; p_tx_rings_t tx_rings; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_hw_kick")); tx_rings = hxgep->tx_rings; if (tx_rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hw_kick: NULL ring pointer")); return; } ndmas = tx_rings->ndmas; if (!ndmas) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hw_kick: no channel allocated")); return; } if (tx_rings->rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hw_kick: NULL rings pointer")); return; } HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_kick: " "tx_rings $%p tx_desc_rings $%p ndmas %d", tx_rings, tx_rings->rings, ndmas)); for (index = 0; index < ndmas; index++) { channel = tx_rings->rings[index]->tdc; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_kick: channel %d", channel)); hxge_txdma_hw_kick_channel(hxgep, tx_rings->rings[index], channel); } HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hw_kick")); } /*ARGSUSED*/ void hxge_txdma_kick_channel(p_hxge_t hxgep, uint16_t channel) { p_tx_ring_t ring_p; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_kick_channel")); ring_p = hxge_txdma_get_ring(hxgep, channel); if (ring_p == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, " hxge_txdma_kick_channel")); return; } if (ring_p->tdc != channel) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_kick_channel: channel not matched " "ring tdc %d passed channel", ring_p->tdc, channel)); return; } hxge_txdma_hw_kick_channel(hxgep, ring_p, channel); HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_kick_channel")); } /*ARGSUSED*/ void hxge_txdma_hw_kick_channel(p_hxge_t hxgep, p_tx_ring_t ring_p, uint16_t channel) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_hw_kick_channel")); if (ring_p == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hw_kick_channel: NULL ring pointer")); return; } HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hw_kick_channel")); } /*ARGSUSED*/ void hxge_check_tx_hang(p_hxge_t hxgep) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_check_tx_hang")); /* * Needs inputs from hardware for regs: head index had not moved since * last timeout. packets not transmitted or stuffed registers. */ if (hxge_txdma_hung(hxgep)) { hxge_fixup_hung_txdma_rings(hxgep); } HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_check_tx_hang")); } int hxge_txdma_hung(p_hxge_t hxgep) { int index, ndmas; uint16_t channel; p_tx_rings_t tx_rings; p_tx_ring_t tx_ring_p; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_hung")); tx_rings = hxgep->tx_rings; if (tx_rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hung: NULL ring pointer")); return (B_FALSE); } ndmas = tx_rings->ndmas; if (!ndmas) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hung: no channel allocated")); return (B_FALSE); } if (tx_rings->rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hung: NULL rings pointer")); return (B_FALSE); } for (index = 0; index < ndmas; index++) { channel = tx_rings->rings[index]->tdc; tx_ring_p = tx_rings->rings[index]; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_hung: channel %d", channel)); if (hxge_txdma_channel_hung(hxgep, tx_ring_p, channel)) { return (B_TRUE); } } HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hung")); return (B_FALSE); } int hxge_txdma_channel_hung(p_hxge_t hxgep, p_tx_ring_t tx_ring_p, uint16_t channel) { uint16_t head_index, tail_index; boolean_t head_wrap, tail_wrap; hpi_handle_t handle; tdc_tdr_head_t tx_head; uint_t tx_rd_index; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_channel_hung")); handle = HXGE_DEV_HPI_HANDLE(hxgep); HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_channel_hung: channel %d", channel)); MUTEX_ENTER(&tx_ring_p->lock); (void) hxge_txdma_reclaim(hxgep, tx_ring_p, 0); tail_index = tx_ring_p->wr_index; tail_wrap = tx_ring_p->wr_index_wrap; tx_rd_index = tx_ring_p->rd_index; MUTEX_EXIT(&tx_ring_p->lock); HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_channel_hung: tdc %d tx_rd_index %d " "tail_index %d tail_wrap %d ", channel, tx_rd_index, tail_index, tail_wrap)); /* * Read the hardware maintained transmit head and wrap around bit. */ (void) hpi_txdma_ring_head_get(handle, channel, &tx_head); head_index = tx_head.bits.head; head_wrap = tx_head.bits.wrap; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_channel_hung: " "tx_rd_index %d tail %d tail_wrap %d head %d wrap %d", tx_rd_index, tail_index, tail_wrap, head_index, head_wrap)); if (TXDMA_RING_EMPTY(head_index, head_wrap, tail_index, tail_wrap) && (head_index == tx_rd_index)) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_channel_hung: EMPTY")); return (B_FALSE); } HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_channel_hung: Checking if ring full")); if (TXDMA_RING_FULL(head_index, head_wrap, tail_index, tail_wrap)) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_channel_hung: full")); return (B_TRUE); } /* If not full, check with hardware to see if it is hung */ HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_channel_hung")); return (B_FALSE); } /*ARGSUSED*/ void hxge_fixup_hung_txdma_rings(p_hxge_t hxgep) { int index, ndmas; uint16_t channel; p_tx_rings_t tx_rings; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_fixup_hung_txdma_rings")); tx_rings = hxgep->tx_rings; if (tx_rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_fixup_hung_txdma_rings: NULL ring pointer")); return; } ndmas = tx_rings->ndmas; if (!ndmas) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_fixup_hung_txdma_rings: no channel allocated")); return; } if (tx_rings->rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_fixup_hung_txdma_rings: NULL rings pointer")); return; } HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_fixup_hung_txdma_rings: " "tx_rings $%p tx_desc_rings $%p ndmas %d", tx_rings, tx_rings->rings, ndmas)); for (index = 0; index < ndmas; index++) { channel = tx_rings->rings[index]->tdc; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_fixup_hung_txdma_rings: channel %d", channel)); hxge_txdma_fixup_hung_channel(hxgep, tx_rings->rings[index], channel); } HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_fixup_hung_txdma_rings")); } /*ARGSUSED*/ void hxge_txdma_fix_hung_channel(p_hxge_t hxgep, uint16_t channel) { p_tx_ring_t ring_p; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_fix_hung_channel")); ring_p = hxge_txdma_get_ring(hxgep, channel); if (ring_p == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_fix_hung_channel")); return; } if (ring_p->tdc != channel) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_fix_hung_channel: channel not matched " "ring tdc %d passed channel", ring_p->tdc, channel)); return; } hxge_txdma_fixup_channel(hxgep, ring_p, channel); HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_fix_hung_channel")); } /*ARGSUSED*/ void hxge_txdma_fixup_hung_channel(p_hxge_t hxgep, p_tx_ring_t ring_p, uint16_t channel) { hpi_handle_t handle; int status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_fixup_hung_channel")); if (ring_p == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_fixup_hung_channel: NULL ring pointer")); return; } if (ring_p->tdc != channel) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_fixup_hung_channel: channel " "not matched ring tdc %d passed channel", ring_p->tdc, channel)); return; } /* Reclaim descriptors */ MUTEX_ENTER(&ring_p->lock); (void) hxge_txdma_reclaim(hxgep, ring_p, 0); MUTEX_EXIT(&ring_p->lock); handle = HXGE_DEV_HPI_HANDLE(hxgep); /* * Stop the dma channel waits for the stop done. If the stop done bit * is not set, then force an error. */ status = hpi_txdma_channel_disable(handle, channel); if (!(status & HPI_TXDMA_STOP_FAILED)) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_fixup_hung_channel: stopped OK " "ring tdc %d passed channel %d", ring_p->tdc, channel)); return; } /* Stop done bit will be set as a result of error injection */ status = hpi_txdma_channel_disable(handle, channel); if (!(status & HPI_TXDMA_STOP_FAILED)) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_fixup_hung_channel: stopped again" "ring tdc %d passed channel", ring_p->tdc, channel)); return; } HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_fixup_hung_channel: stop done still not set!! " "ring tdc %d passed channel", ring_p->tdc, channel)); HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_fixup_hung_channel")); } /*ARGSUSED*/ void hxge_reclaim_rings(p_hxge_t hxgep) { int index, ndmas; uint16_t channel; p_tx_rings_t tx_rings; p_tx_ring_t tx_ring_p; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_reclaim_ring")); tx_rings = hxgep->tx_rings; if (tx_rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_reclain_rimgs: NULL ring pointer")); return; } ndmas = tx_rings->ndmas; if (!ndmas) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_reclain_rimgs: no channel allocated")); return; } if (tx_rings->rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_reclain_rimgs: NULL rings pointer")); return; } HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_reclain_rimgs: " "tx_rings $%p tx_desc_rings $%p ndmas %d", tx_rings, tx_rings->rings, ndmas)); for (index = 0; index < ndmas; index++) { channel = tx_rings->rings[index]->tdc; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> reclain_rimgs: channel %d", channel)); tx_ring_p = tx_rings->rings[index]; MUTEX_ENTER(&tx_ring_p->lock); (void) hxge_txdma_reclaim(hxgep, tx_ring_p, channel); MUTEX_EXIT(&tx_ring_p->lock); } HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_reclaim_rings")); } /* * Static functions start here. */ static hxge_status_t hxge_map_txdma(p_hxge_t hxgep) { int i, ndmas; uint16_t channel; p_tx_rings_t tx_rings; p_tx_ring_t *tx_desc_rings; p_tx_mbox_areas_t tx_mbox_areas_p; p_tx_mbox_t *tx_mbox_p; p_hxge_dma_pool_t dma_buf_poolp; p_hxge_dma_pool_t dma_cntl_poolp; p_hxge_dma_common_t *dma_buf_p; p_hxge_dma_common_t *dma_cntl_p; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma")); dma_buf_poolp = hxgep->tx_buf_pool_p; dma_cntl_poolp = hxgep->tx_cntl_pool_p; if (!dma_buf_poolp->buf_allocated || !dma_cntl_poolp->buf_allocated) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_map_txdma: buf not allocated")); return (HXGE_ERROR); } ndmas = dma_buf_poolp->ndmas; if (!ndmas) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_map_txdma: no dma allocated")); return (HXGE_ERROR); } dma_buf_p = dma_buf_poolp->dma_buf_pool_p; dma_cntl_p = dma_cntl_poolp->dma_buf_pool_p; tx_rings = (p_tx_rings_t)KMEM_ZALLOC(sizeof (tx_rings_t), KM_SLEEP); tx_desc_rings = (p_tx_ring_t *)KMEM_ZALLOC( sizeof (p_tx_ring_t) * ndmas, KM_SLEEP); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma: " "tx_rings $%p tx_desc_rings $%p", tx_rings, tx_desc_rings)); tx_mbox_areas_p = (p_tx_mbox_areas_t) KMEM_ZALLOC(sizeof (tx_mbox_areas_t), KM_SLEEP); tx_mbox_p = (p_tx_mbox_t *)KMEM_ZALLOC( sizeof (p_tx_mbox_t) * ndmas, KM_SLEEP); /* * Map descriptors from the buffer pools for each dma channel. */ for (i = 0; i < ndmas; i++) { /* * Set up and prepare buffer blocks, descriptors and mailbox. */ channel = ((p_hxge_dma_common_t)dma_buf_p[i])->dma_channel; status = hxge_map_txdma_channel(hxgep, channel, (p_hxge_dma_common_t *)&dma_buf_p[i], (p_tx_ring_t *)&tx_desc_rings[i], dma_buf_poolp->num_chunks[i], (p_hxge_dma_common_t *)&dma_cntl_p[i], (p_tx_mbox_t *)&tx_mbox_p[i]); if (status != HXGE_OK) { goto hxge_map_txdma_fail1; } tx_desc_rings[i]->index = (uint16_t)i; tx_desc_rings[i]->tdc_stats = &hxgep->statsp->tdc_stats[i]; } tx_rings->ndmas = ndmas; tx_rings->rings = tx_desc_rings; hxgep->tx_rings = tx_rings; tx_mbox_areas_p->txmbox_areas_p = tx_mbox_p; hxgep->tx_mbox_areas_p = tx_mbox_areas_p; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma: " "tx_rings $%p rings $%p", hxgep->tx_rings, hxgep->tx_rings->rings)); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma: " "tx_rings $%p tx_desc_rings $%p", hxgep->tx_rings, tx_desc_rings)); goto hxge_map_txdma_exit; hxge_map_txdma_fail1: HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma: uninit tx desc " "(status 0x%x channel %d i %d)", hxgep, status, channel, i)); i--; for (; i >= 0; i--) { channel = ((p_hxge_dma_common_t)dma_buf_p[i])->dma_channel; hxge_unmap_txdma_channel(hxgep, channel, tx_desc_rings[i], tx_mbox_p[i]); } KMEM_FREE(tx_desc_rings, sizeof (p_tx_ring_t) * ndmas); KMEM_FREE(tx_rings, sizeof (tx_rings_t)); KMEM_FREE(tx_mbox_p, sizeof (p_tx_mbox_t) * ndmas); KMEM_FREE(tx_mbox_areas_p, sizeof (tx_mbox_areas_t)); hxge_map_txdma_exit: HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma: (status 0x%x channel %d)", status, channel)); return (status); } static void hxge_unmap_txdma(p_hxge_t hxgep) { int i, ndmas; uint8_t channel; p_tx_rings_t tx_rings; p_tx_ring_t *tx_desc_rings; p_tx_mbox_areas_t tx_mbox_areas_p; p_tx_mbox_t *tx_mbox_p; p_hxge_dma_pool_t dma_buf_poolp; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_unmap_txdma")); dma_buf_poolp = hxgep->tx_buf_pool_p; if (!dma_buf_poolp->buf_allocated) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_unmap_txdma: buf not allocated")); return; } ndmas = dma_buf_poolp->ndmas; if (!ndmas) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_unmap_txdma: no dma allocated")); return; } tx_rings = hxgep->tx_rings; tx_desc_rings = tx_rings->rings; if (tx_rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_unmap_txdma: NULL ring pointer")); return; } tx_desc_rings = tx_rings->rings; if (tx_desc_rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_unmap_txdma: NULL ring pointers")); return; } HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_unmap_txdma: " "tx_rings $%p tx_desc_rings $%p ndmas %d", tx_rings, tx_desc_rings, ndmas)); tx_mbox_areas_p = hxgep->tx_mbox_areas_p; tx_mbox_p = tx_mbox_areas_p->txmbox_areas_p; for (i = 0; i < ndmas; i++) { channel = tx_desc_rings[i]->tdc; (void) hxge_unmap_txdma_channel(hxgep, channel, (p_tx_ring_t)tx_desc_rings[i], (p_tx_mbox_t)tx_mbox_p[i]); } KMEM_FREE(tx_desc_rings, sizeof (p_tx_ring_t) * ndmas); KMEM_FREE(tx_rings, sizeof (tx_rings_t)); KMEM_FREE(tx_mbox_p, sizeof (p_tx_mbox_t) * ndmas); KMEM_FREE(tx_mbox_areas_p, sizeof (tx_mbox_areas_t)); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_unmap_txdma")); } static hxge_status_t hxge_map_txdma_channel(p_hxge_t hxgep, uint16_t channel, p_hxge_dma_common_t *dma_buf_p, p_tx_ring_t *tx_desc_p, uint32_t num_chunks, p_hxge_dma_common_t *dma_cntl_p, p_tx_mbox_t *tx_mbox_p) { int status = HXGE_OK; /* * Set up and prepare buffer blocks, descriptors and mailbox. */ HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma_channel (channel %d)", channel)); /* * Transmit buffer blocks */ status = hxge_map_txdma_channel_buf_ring(hxgep, channel, dma_buf_p, tx_desc_p, num_chunks); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_map_txdma_channel (channel %d): " "map buffer failed 0x%x", channel, status)); goto hxge_map_txdma_channel_exit; } /* * Transmit block ring, and mailbox. */ hxge_map_txdma_channel_cfg_ring(hxgep, channel, dma_cntl_p, *tx_desc_p, tx_mbox_p); goto hxge_map_txdma_channel_exit; hxge_map_txdma_channel_fail1: HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma_channel: unmap buf" "(status 0x%x channel %d)", status, channel)); hxge_unmap_txdma_channel_buf_ring(hxgep, *tx_desc_p); hxge_map_txdma_channel_exit: HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_map_txdma_channel: (status 0x%x channel %d)", status, channel)); return (status); } /*ARGSUSED*/ static void hxge_unmap_txdma_channel(p_hxge_t hxgep, uint16_t channel, p_tx_ring_t tx_ring_p, p_tx_mbox_t tx_mbox_p) { HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_unmap_txdma_channel (channel %d)", channel)); /* unmap tx block ring, and mailbox. */ (void) hxge_unmap_txdma_channel_cfg_ring(hxgep, tx_ring_p, tx_mbox_p); /* unmap buffer blocks */ (void) hxge_unmap_txdma_channel_buf_ring(hxgep, tx_ring_p); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_unmap_txdma_channel")); } /*ARGSUSED*/ static void hxge_map_txdma_channel_cfg_ring(p_hxge_t hxgep, uint16_t dma_channel, p_hxge_dma_common_t *dma_cntl_p, p_tx_ring_t tx_ring_p, p_tx_mbox_t *tx_mbox_p) { p_tx_mbox_t mboxp; p_hxge_dma_common_t cntl_dmap; p_hxge_dma_common_t dmap; tdc_tdr_cfg_t *tx_ring_cfig_p; tdc_tdr_kick_t *tx_ring_kick_p; tdc_tdr_cfg_t *tx_cs_p; tdc_int_mask_t *tx_evmask_p; tdc_mbh_t *mboxh_p; tdc_mbl_t *mboxl_p; uint64_t tx_desc_len; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma_channel_cfg_ring")); cntl_dmap = *dma_cntl_p; dmap = (p_hxge_dma_common_t)&tx_ring_p->tdc_desc; hxge_setup_dma_common(dmap, cntl_dmap, tx_ring_p->tx_ring_size, sizeof (tx_desc_t)); /* * Zero out transmit ring descriptors. */ bzero((caddr_t)dmap->kaddrp, dmap->alength); tx_ring_cfig_p = &(tx_ring_p->tx_ring_cfig); tx_ring_kick_p = &(tx_ring_p->tx_ring_kick); tx_cs_p = &(tx_ring_p->tx_cs); tx_evmask_p = &(tx_ring_p->tx_evmask); tx_ring_cfig_p->value = 0; tx_ring_kick_p->value = 0; tx_cs_p->value = 0; tx_evmask_p->value = 0; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma_channel_cfg_ring: channel %d des $%p", dma_channel, dmap->dma_cookie.dmac_laddress)); tx_ring_cfig_p->value = 0; /* Hydra len is 11 bits and the lower 5 bits are 0s */ tx_desc_len = (uint64_t)(tx_ring_p->tx_ring_size >> 5); tx_ring_cfig_p->value = (dmap->dma_cookie.dmac_laddress & TDC_TDR_CFG_ADDR_MASK) | (tx_desc_len << TDC_TDR_CFG_LEN_SHIFT); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma_channel_cfg_ring: channel %d cfg 0x%llx", dma_channel, tx_ring_cfig_p->value)); tx_cs_p->bits.reset = 1; /* Map in mailbox */ mboxp = (p_tx_mbox_t)KMEM_ZALLOC(sizeof (tx_mbox_t), KM_SLEEP); dmap = (p_hxge_dma_common_t)&mboxp->tx_mbox; hxge_setup_dma_common(dmap, cntl_dmap, 1, sizeof (txdma_mailbox_t)); mboxh_p = (tdc_mbh_t *)&tx_ring_p->tx_mbox_mbh; mboxl_p = (tdc_mbl_t *)&tx_ring_p->tx_mbox_mbl; mboxh_p->value = mboxl_p->value = 0; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma_channel_cfg_ring: mbox 0x%lx", dmap->dma_cookie.dmac_laddress)); mboxh_p->bits.mbaddr = ((dmap->dma_cookie.dmac_laddress >> TDC_MBH_ADDR_SHIFT) & TDC_MBH_MASK); mboxl_p->bits.mbaddr = ((dmap->dma_cookie.dmac_laddress & TDC_MBL_MASK) >> TDC_MBL_SHIFT); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma_channel_cfg_ring: mbox 0x%lx", dmap->dma_cookie.dmac_laddress)); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma_channel_cfg_ring: hmbox $%p mbox $%p", mboxh_p->bits.mbaddr, mboxl_p->bits.mbaddr)); /* * Set page valid and no mask */ tx_ring_p->page_hdl.value = 0; *tx_mbox_p = mboxp; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_map_txdma_channel_cfg_ring")); } /*ARGSUSED*/ static void hxge_unmap_txdma_channel_cfg_ring(p_hxge_t hxgep, p_tx_ring_t tx_ring_p, p_tx_mbox_t tx_mbox_p) { HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_unmap_txdma_channel_cfg_ring: channel %d", tx_ring_p->tdc)); KMEM_FREE(tx_mbox_p, sizeof (tx_mbox_t)); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_unmap_txdma_channel_cfg_ring")); } static hxge_status_t hxge_map_txdma_channel_buf_ring(p_hxge_t hxgep, uint16_t channel, p_hxge_dma_common_t *dma_buf_p, p_tx_ring_t *tx_desc_p, uint32_t num_chunks) { p_hxge_dma_common_t dma_bufp, tmp_bufp; p_hxge_dma_common_t dmap; hxge_os_dma_handle_t tx_buf_dma_handle; p_tx_ring_t tx_ring_p; p_tx_msg_t tx_msg_ring; hxge_status_t status = HXGE_OK; int ddi_status = DDI_SUCCESS; int i, j, index; uint32_t size, bsize; uint32_t nblocks, nmsgs; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma_channel_buf_ring")); dma_bufp = tmp_bufp = *dma_buf_p; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, " hxge_map_txdma_channel_buf_ring: channel %d to map %d " "chunks bufp $%p", channel, num_chunks, dma_bufp)); nmsgs = 0; for (i = 0; i < num_chunks; i++, tmp_bufp++) { nmsgs += tmp_bufp->nblocks; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma_channel_buf_ring: channel %d " "bufp $%p nblocks %d nmsgs %d", channel, tmp_bufp, tmp_bufp->nblocks, nmsgs)); } if (!nmsgs) { HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_map_txdma_channel_buf_ring: channel %d " "no msg blocks", channel)); status = HXGE_ERROR; goto hxge_map_txdma_channel_buf_ring_exit; } tx_ring_p = (p_tx_ring_t)KMEM_ZALLOC(sizeof (tx_ring_t), KM_SLEEP); MUTEX_INIT(&tx_ring_p->lock, NULL, MUTEX_DRIVER, (void *) hxgep->interrupt_cookie); /* * Allocate transmit message rings and handles for packets not to be * copied to premapped buffers. */ size = nmsgs * sizeof (tx_msg_t); tx_msg_ring = KMEM_ZALLOC(size, KM_SLEEP); for (i = 0; i < nmsgs; i++) { ddi_status = ddi_dma_alloc_handle(hxgep->dip, &hxge_tx_dma_attr, DDI_DMA_DONTWAIT, 0, &tx_msg_ring[i].dma_handle); if (ddi_status != DDI_SUCCESS) { status |= HXGE_DDI_FAILED; break; } } if (i < nmsgs) { HXGE_DEBUG_MSG((hxgep, HXGE_ERR_CTL, "Allocate handles failed.")); goto hxge_map_txdma_channel_buf_ring_fail1; } tx_ring_p->tdc = channel; tx_ring_p->tx_msg_ring = tx_msg_ring; tx_ring_p->tx_ring_size = nmsgs; tx_ring_p->num_chunks = num_chunks; if (!hxge_tx_intr_thres) { hxge_tx_intr_thres = tx_ring_p->tx_ring_size / 4; } tx_ring_p->tx_wrap_mask = tx_ring_p->tx_ring_size - 1; tx_ring_p->rd_index = 0; tx_ring_p->wr_index = 0; tx_ring_p->ring_head.value = 0; tx_ring_p->ring_kick_tail.value = 0; tx_ring_p->descs_pending = 0; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma_channel_buf_ring: channel %d " "actual tx desc max %d nmsgs %d (config hxge_tx_ring_size %d)", channel, tx_ring_p->tx_ring_size, nmsgs, hxge_tx_ring_size)); /* * Map in buffers from the buffer pool. */ index = 0; bsize = dma_bufp->block_size; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma_channel_buf_ring: " "dma_bufp $%p tx_rng_p $%p tx_msg_rng_p $%p bsize %d", dma_bufp, tx_ring_p, tx_msg_ring, bsize)); tx_buf_dma_handle = dma_bufp->dma_handle; for (i = 0; i < num_chunks; i++, dma_bufp++) { bsize = dma_bufp->block_size; nblocks = dma_bufp->nblocks; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma_channel_buf_ring: dma chunk %d " "size %d dma_bufp $%p", i, sizeof (hxge_dma_common_t), dma_bufp)); for (j = 0; j < nblocks; j++) { tx_msg_ring[index].buf_dma_handle = tx_buf_dma_handle; dmap = &tx_msg_ring[index++].buf_dma; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_map_txdma_channel_buf_ring: j %d" "dmap $%p", i, dmap)); hxge_setup_dma_common(dmap, dma_bufp, 1, bsize); } } if (i < num_chunks) { status = HXGE_ERROR; goto hxge_map_txdma_channel_buf_ring_fail1; } *tx_desc_p = tx_ring_p; goto hxge_map_txdma_channel_buf_ring_exit; hxge_map_txdma_channel_buf_ring_fail1: index--; for (; index >= 0; index--) { if (tx_msg_ring[index].dma_handle != NULL) { ddi_dma_free_handle(&tx_msg_ring[index].dma_handle); } } MUTEX_DESTROY(&tx_ring_p->lock); KMEM_FREE(tx_msg_ring, size); KMEM_FREE(tx_ring_p, sizeof (tx_ring_t)); status = HXGE_ERROR; hxge_map_txdma_channel_buf_ring_exit: HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_map_txdma_channel_buf_ring status 0x%x", status)); return (status); } /*ARGSUSED*/ static void hxge_unmap_txdma_channel_buf_ring(p_hxge_t hxgep, p_tx_ring_t tx_ring_p) { p_tx_msg_t tx_msg_ring; p_tx_msg_t tx_msg_p; int i; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_unmap_txdma_channel_buf_ring")); if (tx_ring_p == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_unmap_txdma_channel_buf_ring: NULL ringp")); return; } HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_unmap_txdma_channel_buf_ring: channel %d", tx_ring_p->tdc)); tx_msg_ring = tx_ring_p->tx_msg_ring; for (i = 0; i < tx_ring_p->tx_ring_size; i++) { tx_msg_p = &tx_msg_ring[i]; if (tx_msg_p->flags.dma_type == USE_DVMA) { HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "entry = %d", i)); (void) dvma_unload(tx_msg_p->dvma_handle, 0, -1); tx_msg_p->dvma_handle = NULL; if (tx_ring_p->dvma_wr_index == tx_ring_p->dvma_wrap_mask) { tx_ring_p->dvma_wr_index = 0; } else { tx_ring_p->dvma_wr_index++; } tx_ring_p->dvma_pending--; } else if (tx_msg_p->flags.dma_type == USE_DMA) { if (ddi_dma_unbind_handle(tx_msg_p->dma_handle)) { cmn_err(CE_WARN, "hxge_unmap_tx_bug_ring: " "ddi_dma_unbind_handle failed."); } } if (tx_msg_p->tx_message != NULL) { freemsg(tx_msg_p->tx_message); tx_msg_p->tx_message = NULL; } } for (i = 0; i < tx_ring_p->tx_ring_size; i++) { if (tx_msg_ring[i].dma_handle != NULL) { ddi_dma_free_handle(&tx_msg_ring[i].dma_handle); } } MUTEX_DESTROY(&tx_ring_p->lock); KMEM_FREE(tx_msg_ring, sizeof (tx_msg_t) * tx_ring_p->tx_ring_size); KMEM_FREE(tx_ring_p, sizeof (tx_ring_t)); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_unmap_txdma_channel_buf_ring")); } static hxge_status_t hxge_txdma_hw_start(p_hxge_t hxgep) { int i, ndmas; uint16_t channel; p_tx_rings_t tx_rings; p_tx_ring_t *tx_desc_rings; p_tx_mbox_areas_t tx_mbox_areas_p; p_tx_mbox_t *tx_mbox_p; hxge_status_t status = HXGE_OK; uint64_t tmp; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_start")); /* * Initialize REORD Table 1. Disable VMAC 2. Reset the FIFO Err Stat. * 3. Scrub memory and check for errors. */ (void) hxge_tx_vmac_disable(hxgep); /* * Clear the error status */ HXGE_REG_WR64(hxgep->hpi_handle, TDC_FIFO_ERR_STAT, 0x7); /* * Scrub the rtab memory for the TDC and reset the TDC. */ HXGE_REG_WR64(hxgep->hpi_handle, TDC_REORD_TBL_DATA_HI, 0x0ULL); HXGE_REG_WR64(hxgep->hpi_handle, TDC_REORD_TBL_DATA_LO, 0x0ULL); for (i = 0; i < 256; i++) { HXGE_REG_WR64(hxgep->hpi_handle, TDC_REORD_TBL_CMD, (uint64_t)i); /* * Write the command register with an indirect read instruction */ tmp = (0x1ULL << 30) | i; HXGE_REG_WR64(hxgep->hpi_handle, TDC_REORD_TBL_CMD, tmp); /* * Wait for status done */ tmp = 0; do { HXGE_REG_RD64(hxgep->hpi_handle, TDC_REORD_TBL_CMD, &tmp); } while (((tmp >> 31) & 0x1ULL) == 0x0); } for (i = 0; i < 256; i++) { /* * Write the command register with an indirect read instruction */ tmp = (0x1ULL << 30) | i; HXGE_REG_WR64(hxgep->hpi_handle, TDC_REORD_TBL_CMD, tmp); /* * Wait for status done */ tmp = 0; do { HXGE_REG_RD64(hxgep->hpi_handle, TDC_REORD_TBL_CMD, &tmp); } while (((tmp >> 31) & 0x1ULL) == 0x0); HXGE_REG_RD64(hxgep->hpi_handle, TDC_REORD_TBL_DATA_HI, &tmp); if (0x1ff00ULL != (0x1ffffULL & tmp)) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "PANIC ReordTbl " "unexpected data (hi), entry: %x, value: 0x%0llx\n", i, (unsigned long long)tmp)); status = HXGE_ERROR; } HXGE_REG_RD64(hxgep->hpi_handle, TDC_REORD_TBL_DATA_LO, &tmp); if (tmp != 0) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "PANIC ReordTbl " "unexpected data (lo), entry: %x\n", i)); status = HXGE_ERROR; } HXGE_REG_RD64(hxgep->hpi_handle, TDC_FIFO_ERR_STAT, &tmp); if (tmp != 0) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "PANIC ReordTbl " "parity error, entry: %x, val 0x%llx\n", i, (unsigned long long)tmp)); status = HXGE_ERROR; } HXGE_REG_RD64(hxgep->hpi_handle, TDC_FIFO_ERR_STAT, &tmp); if (tmp != 0) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "PANIC ReordTbl " "parity error, entry: %x\n", i)); status = HXGE_ERROR; } } if (status != HXGE_OK) goto hxge_txdma_hw_start_exit; /* * Reset FIFO Error Status for the TDC and enable FIFO error events. */ HXGE_REG_WR64(hxgep->hpi_handle, TDC_FIFO_ERR_STAT, 0x7); HXGE_REG_WR64(hxgep->hpi_handle, TDC_FIFO_ERR_MASK, 0x0); /* * Initialize the Transmit DMAs. */ tx_rings = hxgep->tx_rings; if (tx_rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hw_start: NULL ring pointer")); return (HXGE_ERROR); } tx_desc_rings = tx_rings->rings; if (tx_desc_rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hw_start: NULL ring pointers")); return (HXGE_ERROR); } ndmas = tx_rings->ndmas; if (!ndmas) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hw_start: no dma channel allocated")); return (HXGE_ERROR); } HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_start: " "tx_rings $%p tx_desc_rings $%p ndmas %d", tx_rings, tx_desc_rings, ndmas)); tx_mbox_areas_p = hxgep->tx_mbox_areas_p; tx_mbox_p = tx_mbox_areas_p->txmbox_areas_p; /* * Init the DMAs. */ for (i = 0; i < ndmas; i++) { channel = tx_desc_rings[i]->tdc; status = hxge_txdma_start_channel(hxgep, channel, (p_tx_ring_t)tx_desc_rings[i], (p_tx_mbox_t)tx_mbox_p[i]); if (status != HXGE_OK) { goto hxge_txdma_hw_start_fail1; } } (void) hxge_tx_vmac_enable(hxgep); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_start: tx_rings $%p rings $%p", hxgep->tx_rings, hxgep->tx_rings->rings)); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_start: tx_rings $%p tx_desc_rings $%p", hxgep->tx_rings, tx_desc_rings)); goto hxge_txdma_hw_start_exit; hxge_txdma_hw_start_fail1: HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_start: disable (status 0x%x channel %d i %d)", status, channel, i)); for (; i >= 0; i--) { channel = tx_desc_rings[i]->tdc, (void) hxge_txdma_stop_channel(hxgep, channel, (p_tx_ring_t)tx_desc_rings[i], (p_tx_mbox_t)tx_mbox_p[i]); } hxge_txdma_hw_start_exit: HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_start: (status 0x%x)", status)); return (status); } static void hxge_txdma_hw_stop(p_hxge_t hxgep) { int i, ndmas; uint16_t channel; p_tx_rings_t tx_rings; p_tx_ring_t *tx_desc_rings; p_tx_mbox_areas_t tx_mbox_areas_p; p_tx_mbox_t *tx_mbox_p; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_stop")); tx_rings = hxgep->tx_rings; if (tx_rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hw_stop: NULL ring pointer")); return; } tx_desc_rings = tx_rings->rings; if (tx_desc_rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hw_stop: NULL ring pointers")); return; } ndmas = tx_rings->ndmas; if (!ndmas) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_hw_stop: no dma channel allocated")); return; } HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_stop: " "tx_rings $%p tx_desc_rings $%p", tx_rings, tx_desc_rings)); tx_mbox_areas_p = hxgep->tx_mbox_areas_p; tx_mbox_p = tx_mbox_areas_p->txmbox_areas_p; for (i = 0; i < ndmas; i++) { channel = tx_desc_rings[i]->tdc; (void) hxge_txdma_stop_channel(hxgep, channel, (p_tx_ring_t)tx_desc_rings[i], (p_tx_mbox_t)tx_mbox_p[i]); } HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_hw_stop: " "tx_rings $%p tx_desc_rings $%p", tx_rings, tx_desc_rings)); HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_txdma_hw_stop")); } static hxge_status_t hxge_txdma_start_channel(p_hxge_t hxgep, uint16_t channel, p_tx_ring_t tx_ring_p, p_tx_mbox_t tx_mbox_p) { hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_start_channel (channel %d)", channel)); /* * TXDMA/TXC must be in stopped state. */ (void) hxge_txdma_stop_inj_err(hxgep, channel); /* * Reset TXDMA channel */ tx_ring_p->tx_cs.value = 0; tx_ring_p->tx_cs.bits.reset = 1; status = hxge_reset_txdma_channel(hxgep, channel, tx_ring_p->tx_cs.value); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_txdma_start_channel (channel %d)" " reset channel failed 0x%x", channel, status)); goto hxge_txdma_start_channel_exit; } /* * Initialize the TXDMA channel specific FZC control configurations. * These FZC registers are pertaining to each TX channel (i.e. logical * pages). */ status = hxge_init_fzc_txdma_channel(hxgep, channel, tx_ring_p, tx_mbox_p); if (status != HXGE_OK) { goto hxge_txdma_start_channel_exit; } /* * Initialize the event masks. */ tx_ring_p->tx_evmask.value = 0; status = hxge_init_txdma_channel_event_mask(hxgep, channel, &tx_ring_p->tx_evmask); if (status != HXGE_OK) { goto hxge_txdma_start_channel_exit; } /* * Load TXDMA descriptors, buffers, mailbox, initialise the DMA * channels and enable each DMA channel. */ status = hxge_enable_txdma_channel(hxgep, channel, tx_ring_p, tx_mbox_p); if (status != HXGE_OK) { goto hxge_txdma_start_channel_exit; } hxge_txdma_start_channel_exit: HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_txdma_start_channel")); return (status); } /*ARGSUSED*/ static hxge_status_t hxge_txdma_stop_channel(p_hxge_t hxgep, uint16_t channel, p_tx_ring_t tx_ring_p, p_tx_mbox_t tx_mbox_p) { int status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_stop_channel: channel %d", channel)); /* * Stop (disable) TXDMA and TXC (if stop bit is set and STOP_N_GO bit * not set, the TXDMA reset state will not be set if reset TXDMA. */ (void) hxge_txdma_stop_inj_err(hxgep, channel); /* * Reset TXDMA channel */ tx_ring_p->tx_cs.value = 0; tx_ring_p->tx_cs.bits.reset = 1; status = hxge_reset_txdma_channel(hxgep, channel, tx_ring_p->tx_cs.value); if (status != HXGE_OK) { goto hxge_txdma_stop_channel_exit; } hxge_txdma_stop_channel_exit: HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_txdma_stop_channel")); return (status); } static p_tx_ring_t hxge_txdma_get_ring(p_hxge_t hxgep, uint16_t channel) { int index, ndmas; uint16_t tdc; p_tx_rings_t tx_rings; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_get_ring")); tx_rings = hxgep->tx_rings; if (tx_rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_get_ring: NULL ring pointer")); return (NULL); } ndmas = tx_rings->ndmas; if (!ndmas) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_get_ring: no channel allocated")); return (NULL); } if (tx_rings->rings == NULL) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_get_ring: NULL rings pointer")); return (NULL); } HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_get_ring: " "tx_rings $%p tx_desc_rings $%p ndmas %d", tx_rings, tx_rings, ndmas)); for (index = 0; index < ndmas; index++) { tdc = tx_rings->rings[index]->tdc; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_fixup_txdma_rings: channel %d", tdc)); if (channel == tdc) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_get_ring: tdc %d ring $%p", tdc, tx_rings->rings[index])); return (p_tx_ring_t)(tx_rings->rings[index]); } } HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_get_ring")); return (NULL); } static p_tx_mbox_t hxge_txdma_get_mbox(p_hxge_t hxgep, uint16_t channel) { int index, tdc, ndmas; p_tx_rings_t tx_rings; p_tx_mbox_areas_t tx_mbox_areas_p; p_tx_mbox_t *tx_mbox_p; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_get_mbox")); tx_rings = hxgep->tx_rings; if (tx_rings == NULL) { HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_txdma_get_mbox: NULL ring pointer")); return (NULL); } tx_mbox_areas_p = hxgep->tx_mbox_areas_p; if (tx_mbox_areas_p == NULL) { HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_txdma_get_mbox: NULL mbox pointer")); return (NULL); } tx_mbox_p = tx_mbox_areas_p->txmbox_areas_p; ndmas = tx_rings->ndmas; if (!ndmas) { HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_txdma_get_mbox: no channel allocated")); return (NULL); } if (tx_rings->rings == NULL) { HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "<== hxge_txdma_get_mbox: NULL rings pointer")); return (NULL); } HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_get_mbox: " "tx_rings $%p tx_desc_rings $%p ndmas %d", tx_rings, tx_rings, ndmas)); for (index = 0; index < ndmas; index++) { tdc = tx_rings->rings[index]->tdc; HXGE_DEBUG_MSG((hxgep, MEM3_CTL, "==> hxge_txdma_get_mbox: channel %d", tdc)); if (channel == tdc) { HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_get_mbox: tdc %d ring $%p", tdc, tx_rings->rings[index])); return (p_tx_mbox_t)(tx_mbox_p[index]); } } HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_get_mbox")); return (NULL); } /*ARGSUSED*/ static hxge_status_t hxge_tx_err_evnts(p_hxge_t hxgep, uint_t index, p_hxge_ldv_t ldvp, tdc_stat_t cs) { hpi_handle_t handle; uint8_t channel; p_tx_ring_t *tx_rings; p_tx_ring_t tx_ring_p; p_hxge_tx_ring_stats_t tdc_stats; boolean_t txchan_fatal = B_FALSE; hxge_status_t status = HXGE_OK; tdc_drop_cnt_t drop_cnt; HXGE_DEBUG_MSG((hxgep, TX_ERR_CTL, "==> hxge_tx_err_evnts")); handle = HXGE_DEV_HPI_HANDLE(hxgep); channel = ldvp->channel; tx_rings = hxgep->tx_rings->rings; tx_ring_p = tx_rings[index]; tdc_stats = tx_ring_p->tdc_stats; /* Get the error counts if any */ TXDMA_REG_READ64(handle, TDC_DROP_CNT, channel, &drop_cnt.value); tdc_stats->count_hdr_size_err += drop_cnt.bits.hdr_size_error_count; tdc_stats->count_runt += drop_cnt.bits.runt_count; tdc_stats->count_abort += drop_cnt.bits.abort_count; if (cs.bits.peu_resp_err) { tdc_stats->peu_resp_err++; HXGE_FM_REPORT_ERROR(hxgep, channel, HXGE_FM_EREPORT_TDMC_PEU_RESP_ERR); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_tx_err_evnts(channel %d): " "fatal error: peu_resp_err", channel)); txchan_fatal = B_TRUE; } if (cs.bits.pkt_size_hdr_err) { tdc_stats->pkt_size_hdr_err++; HXGE_FM_REPORT_ERROR(hxgep, channel, HXGE_FM_EREPORT_TDMC_PKT_SIZE_HDR_ERR); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_tx_err_evnts(channel %d): " "fatal error: pkt_size_hdr_err", channel)); txchan_fatal = B_TRUE; } if (cs.bits.runt_pkt_drop_err) { tdc_stats->runt_pkt_drop_err++; HXGE_FM_REPORT_ERROR(hxgep, channel, HXGE_FM_EREPORT_TDMC_RUNT_PKT_DROP_ERR); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_tx_err_evnts(channel %d): " "fatal error: runt_pkt_drop_err", channel)); txchan_fatal = B_TRUE; } if (cs.bits.pkt_size_err) { tdc_stats->pkt_size_err++; HXGE_FM_REPORT_ERROR(hxgep, channel, HXGE_FM_EREPORT_TDMC_PKT_SIZE_ERR); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_tx_err_evnts(channel %d): " "fatal error: pkt_size_err", channel)); txchan_fatal = B_TRUE; } if (cs.bits.tx_rng_oflow) { tdc_stats->tx_rng_oflow++; if (tdc_stats->tx_rng_oflow) HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_tx_err_evnts(channel %d): " "fatal error: tx_rng_oflow", channel)); } if (cs.bits.pref_par_err) { tdc_stats->pref_par_err++; /* Get the address of parity error read data */ TXDMA_REG_READ64(hxgep->hpi_handle, TDC_PREF_PAR_LOG, channel, &tdc_stats->errlog.value); HXGE_FM_REPORT_ERROR(hxgep, channel, HXGE_FM_EREPORT_TDMC_PREF_PAR_ERR); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_tx_err_evnts(channel %d): " "fatal error: pref_par_err", channel)); txchan_fatal = B_TRUE; } if (cs.bits.tdr_pref_cpl_to) { tdc_stats->tdr_pref_cpl_to++; HXGE_FM_REPORT_ERROR(hxgep, channel, HXGE_FM_EREPORT_TDMC_TDR_PREF_CPL_TO); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_tx_err_evnts(channel %d): " "fatal error: tdr_pref_cpl_to", channel)); txchan_fatal = B_TRUE; } if (cs.bits.pkt_cpl_to) { tdc_stats->pkt_cpl_to++; HXGE_FM_REPORT_ERROR(hxgep, channel, HXGE_FM_EREPORT_TDMC_PKT_CPL_TO); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_tx_err_evnts(channel %d): " "fatal error: pkt_cpl_to", channel)); txchan_fatal = B_TRUE; } if (cs.bits.invalid_sop) { tdc_stats->invalid_sop++; HXGE_FM_REPORT_ERROR(hxgep, channel, HXGE_FM_EREPORT_TDMC_INVALID_SOP); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_tx_err_evnts(channel %d): " "fatal error: invalid_sop", channel)); txchan_fatal = B_TRUE; } if (cs.bits.unexpected_sop) { tdc_stats->unexpected_sop++; HXGE_FM_REPORT_ERROR(hxgep, channel, HXGE_FM_EREPORT_TDMC_UNEXPECTED_SOP); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_tx_err_evnts(channel %d): " "fatal error: unexpected_sop", channel)); txchan_fatal = B_TRUE; } /* Clear error injection source in case this is an injected error */ TXDMA_REG_WRITE64(hxgep->hpi_handle, TDC_STAT_INT_DBG, channel, 0); if (txchan_fatal) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_tx_err_evnts: " " fatal error on channel %d cs 0x%llx\n", channel, cs.value)); status = hxge_txdma_fatal_err_recover(hxgep, channel, tx_ring_p); if (status == HXGE_OK) { FM_SERVICE_RESTORED(hxgep); } } HXGE_DEBUG_MSG((hxgep, TX_ERR_CTL, "<== hxge_tx_err_evnts")); return (status); } hxge_status_t hxge_txdma_handle_sys_errors(p_hxge_t hxgep) { hpi_handle_t handle; hxge_status_t status = HXGE_OK; tdc_fifo_err_stat_t fifo_stat; hxge_tdc_sys_stats_t *tdc_sys_stats; HXGE_DEBUG_MSG((hxgep, TX_CTL, "==> hxge_txdma_handle_sys_errors")); handle = HXGE_DEV_HPI_HANDLE(hxgep); /* * The FIFO is shared by all channels. * Get the status of Reorder Buffer and Reorder Table Buffer Errors */ HXGE_REG_RD64(handle, TDC_FIFO_ERR_STAT, &fifo_stat.value); /* * Clear the error bits. Note that writing a 1 clears the bit. Writing * a 0 does nothing. */ HXGE_REG_WR64(handle, TDC_FIFO_ERR_STAT, fifo_stat.value); tdc_sys_stats = &hxgep->statsp->tdc_sys_stats; if (fifo_stat.bits.reord_tbl_par_err) { tdc_sys_stats->reord_tbl_par_err++; HXGE_FM_REPORT_ERROR(hxgep, NULL, HXGE_FM_EREPORT_TDMC_REORD_TBL_PAR); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_txdma_handle_sys_errors: fatal error: " "reord_tbl_par_err")); } if (fifo_stat.bits.reord_buf_ded_err) { tdc_sys_stats->reord_buf_ded_err++; HXGE_FM_REPORT_ERROR(hxgep, NULL, HXGE_FM_EREPORT_TDMC_REORD_BUF_DED); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_txdma_handle_sys_errors: " "fatal error: reord_buf_ded_err")); } if (fifo_stat.bits.reord_buf_sec_err) { tdc_sys_stats->reord_buf_sec_err++; if (tdc_sys_stats->reord_buf_sec_err == 1) HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_txdma_handle_sys_errors: " "reord_buf_sec_err")); } if (fifo_stat.bits.reord_tbl_par_err || fifo_stat.bits.reord_buf_ded_err) { status = hxge_tx_port_fatal_err_recover(hxgep); if (status == HXGE_OK) { FM_SERVICE_RESTORED(hxgep); } } HXGE_DEBUG_MSG((hxgep, TX_CTL, "<== hxge_txdma_handle_sys_errors")); return (status); } static hxge_status_t hxge_txdma_fatal_err_recover(p_hxge_t hxgep, uint16_t channel, p_tx_ring_t tx_ring_p) { hpi_handle_t handle; hpi_status_t rs = HPI_SUCCESS; p_tx_mbox_t tx_mbox_p; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, TX_ERR_CTL, "==> hxge_txdma_fatal_err_recover")); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "Recovering from TxDMAChannel#%d error...", channel)); /* * Stop the dma channel waits for the stop done. If the stop done bit * is not set, then create an error. */ handle = HXGE_DEV_HPI_HANDLE(hxgep); HXGE_DEBUG_MSG((hxgep, TX_ERR_CTL, "stopping txdma channel(%d)", channel)); MUTEX_ENTER(&tx_ring_p->lock); rs = hpi_txdma_channel_control(handle, TXDMA_STOP, channel); if (rs != HPI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_txdma_fatal_err_recover (channel %d): " "stop failed ", channel)); goto fail; } HXGE_DEBUG_MSG((hxgep, TX_ERR_CTL, "reclaiming txdma channel(%d)", channel)); (void) hxge_txdma_reclaim(hxgep, tx_ring_p, 0); /* * Reset TXDMA channel */ HXGE_DEBUG_MSG((hxgep, TX_ERR_CTL, "resetting txdma channel(%d)", channel)); if ((rs = hpi_txdma_channel_control(handle, TXDMA_RESET, channel)) != HPI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_txdma_fatal_err_recover (channel %d)" " reset channel failed 0x%x", channel, rs)); goto fail; } /* * Reset the tail (kick) register to 0. (Hardware will not reset it. Tx * overflow fatal error if tail is not set to 0 after reset! */ TXDMA_REG_WRITE64(handle, TDC_TDR_KICK, channel, 0); /* * Restart TXDMA channel * * Initialize the TXDMA channel specific FZC control configurations. * These FZC registers are pertaining to each TX channel (i.e. logical * pages). */ tx_mbox_p = hxge_txdma_get_mbox(hxgep, channel); HXGE_DEBUG_MSG((hxgep, TX_ERR_CTL, "restarting txdma channel(%d)", channel)); status = hxge_init_fzc_txdma_channel(hxgep, channel, tx_ring_p, tx_mbox_p); if (status != HXGE_OK) goto fail; /* * Initialize the event masks. */ tx_ring_p->tx_evmask.value = 0; status = hxge_init_txdma_channel_event_mask(hxgep, channel, &tx_ring_p->tx_evmask); if (status != HXGE_OK) goto fail; tx_ring_p->wr_index_wrap = B_FALSE; tx_ring_p->wr_index = 0; tx_ring_p->rd_index = 0; /* * Load TXDMA descriptors, buffers, mailbox, initialise the DMA * channels and enable each DMA channel. */ HXGE_DEBUG_MSG((hxgep, TX_ERR_CTL, "enabling txdma channel(%d)", channel)); status = hxge_enable_txdma_channel(hxgep, channel, tx_ring_p, tx_mbox_p); MUTEX_EXIT(&tx_ring_p->lock); if (status != HXGE_OK) goto fail; HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "Recovery Successful, TxDMAChannel#%d Restored", channel)); HXGE_DEBUG_MSG((hxgep, TX_ERR_CTL, "==> hxge_txdma_fatal_err_recover")); return (HXGE_OK); fail: MUTEX_EXIT(&tx_ring_p->lock); HXGE_DEBUG_MSG((hxgep, TX_ERR_CTL, "hxge_txdma_fatal_err_recover (channel %d): " "failed to recover this txdma channel", channel)); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "Recovery failed")); return (status); } static hxge_status_t hxge_tx_port_fatal_err_recover(p_hxge_t hxgep) { hpi_handle_t handle; hpi_status_t rs = HPI_SUCCESS; hxge_status_t status = HXGE_OK; p_tx_ring_t *tx_desc_rings; p_tx_rings_t tx_rings; p_tx_ring_t tx_ring_p; int i, ndmas; uint16_t channel; block_reset_t reset_reg; HXGE_DEBUG_MSG((hxgep, TX_ERR_CTL, "==> hxge_tx_port_fatal_err_recover")); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "Recovering from TxPort error...")); handle = HXGE_DEV_HPI_HANDLE(hxgep); /* Reset TDC block from PEU for this fatal error */ reset_reg.value = 0; reset_reg.bits.tdc_rst = 1; HXGE_REG_WR32(handle, BLOCK_RESET, reset_reg.value); HXGE_DELAY(1000); /* * Stop the dma channel waits for the stop done. If the stop done bit * is not set, then create an error. */ HXGE_DEBUG_MSG((hxgep, TX_ERR_CTL, "stopping all DMA channels...")); tx_rings = hxgep->tx_rings; tx_desc_rings = tx_rings->rings; ndmas = tx_rings->ndmas; for (i = 0; i < ndmas; i++) { if (tx_desc_rings[i] == NULL) { continue; } tx_ring_p = tx_rings->rings[i]; MUTEX_ENTER(&tx_ring_p->lock); } for (i = 0; i < ndmas; i++) { if (tx_desc_rings[i] == NULL) { continue; } channel = tx_desc_rings[i]->tdc; tx_ring_p = tx_rings->rings[i]; rs = hpi_txdma_channel_control(handle, TXDMA_STOP, channel); if (rs != HPI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "==> hxge_txdma_fatal_err_recover (channel %d): " "stop failed ", channel)); goto fail; } } /* * Do reclaim on all of th DMAs. */ HXGE_DEBUG_MSG((hxgep, TX_ERR_CTL, "reclaiming all DMA channels...")); for (i = 0; i < ndmas; i++) { if (tx_desc_rings[i] == NULL) { continue; } tx_ring_p = tx_rings->rings[i]; (void) hxge_txdma_reclaim(hxgep, tx_ring_p, 0); } /* Restart the TDC */ if ((status = hxge_txdma_hw_start(hxgep)) != HXGE_OK) goto fail; for (i = 0; i < ndmas; i++) { if (tx_desc_rings[i] == NULL) { continue; } tx_ring_p = tx_rings->rings[i]; MUTEX_EXIT(&tx_ring_p->lock); } HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "Recovery Successful, TxPort Restored")); HXGE_DEBUG_MSG((hxgep, TX_ERR_CTL, "<== hxge_tx_port_fatal_err_recover")); return (HXGE_OK); fail: for (i = 0; i < ndmas; i++) { if (tx_desc_rings[i] == NULL) { continue; } tx_ring_p = tx_rings->rings[i]; MUTEX_EXIT(&tx_ring_p->lock); } HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "Recovery failed")); HXGE_DEBUG_MSG((hxgep, TX_ERR_CTL, "hxge_txdma_fatal_err_recover (channel %d): " "failed to recover this txdma channel")); return (status); }