/* * 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 2009 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #include #include #include #if !defined(_BIG_ENDIAN) #include #endif #include #include #define NXGE_ACTUAL_RDCGRP(nxgep, rdcgrp) \ (rdcgrp + nxgep->pt_config.hw_config.def_mac_rxdma_grpid) #define NXGE_ACTUAL_RDC(nxgep, rdc) \ (rdc + nxgep->pt_config.hw_config.start_rdc) /* * Globals: tunable parameters (/etc/system or adb) * */ extern uint32_t nxge_rbr_size; extern uint32_t nxge_rcr_size; extern uint32_t nxge_rbr_spare_size; extern uint16_t nxge_rdc_buf_offset; extern uint32_t nxge_mblks_pending; /* * Tunable to reduce the amount of time spent in the * ISR doing Rx Processing. */ extern uint32_t nxge_max_rx_pkts; /* * Tunables to manage the receive buffer blocks. * * nxge_rx_threshold_hi: copy all buffers. * nxge_rx_bcopy_size_type: receive buffer block size type. * nxge_rx_threshold_lo: copy only up to tunable block size type. */ extern nxge_rxbuf_threshold_t nxge_rx_threshold_hi; extern nxge_rxbuf_type_t nxge_rx_buf_size_type; extern nxge_rxbuf_threshold_t nxge_rx_threshold_lo; extern uint32_t nxge_cksum_offload; static nxge_status_t nxge_map_rxdma(p_nxge_t, int); static void nxge_unmap_rxdma(p_nxge_t, int); static nxge_status_t nxge_rxdma_hw_start_common(p_nxge_t); static nxge_status_t nxge_rxdma_hw_start(p_nxge_t, int); static void nxge_rxdma_hw_stop(p_nxge_t, int); static nxge_status_t nxge_map_rxdma_channel(p_nxge_t, uint16_t, p_nxge_dma_common_t *, p_rx_rbr_ring_t *, uint32_t, p_nxge_dma_common_t *, p_rx_rcr_ring_t *, p_rx_mbox_t *); static void nxge_unmap_rxdma_channel(p_nxge_t, uint16_t, p_rx_rbr_ring_t, p_rx_rcr_ring_t, p_rx_mbox_t); static nxge_status_t nxge_map_rxdma_channel_cfg_ring(p_nxge_t, uint16_t, p_nxge_dma_common_t *, p_rx_rbr_ring_t *, p_rx_rcr_ring_t *, p_rx_mbox_t *); static void nxge_unmap_rxdma_channel_cfg_ring(p_nxge_t, p_rx_rcr_ring_t, p_rx_mbox_t); static nxge_status_t nxge_map_rxdma_channel_buf_ring(p_nxge_t, uint16_t, p_nxge_dma_common_t *, p_rx_rbr_ring_t *, uint32_t); static void nxge_unmap_rxdma_channel_buf_ring(p_nxge_t, p_rx_rbr_ring_t); static nxge_status_t nxge_rxdma_start_channel(p_nxge_t, uint16_t, p_rx_rbr_ring_t, p_rx_rcr_ring_t, p_rx_mbox_t); static nxge_status_t nxge_rxdma_stop_channel(p_nxge_t, uint16_t); static mblk_t * nxge_rx_pkts(p_nxge_t, p_rx_rcr_ring_t, rx_dma_ctl_stat_t, int); static void nxge_receive_packet(p_nxge_t, p_rx_rcr_ring_t, p_rcr_entry_t, boolean_t *, mblk_t **, mblk_t **); nxge_status_t nxge_disable_rxdma_channel(p_nxge_t, uint16_t); static p_rx_msg_t nxge_allocb(size_t, uint32_t, p_nxge_dma_common_t); static void nxge_freeb(p_rx_msg_t); static nxge_status_t nxge_rx_err_evnts(p_nxge_t, int, rx_dma_ctl_stat_t); static nxge_status_t nxge_rxdma_handle_port_errors(p_nxge_t, uint32_t, uint32_t); static nxge_status_t nxge_rxbuf_index_info_init(p_nxge_t, p_rx_rbr_ring_t); static nxge_status_t nxge_rxdma_fatal_err_recover(p_nxge_t, uint16_t); nxge_status_t nxge_rx_port_fatal_err_recover(p_nxge_t); static void nxge_rxdma_databuf_free(p_rx_rbr_ring_t); nxge_status_t nxge_init_rxdma_channels(p_nxge_t nxgep) { nxge_grp_set_t *set = &nxgep->rx_set; int i, count, channel; nxge_grp_t *group; dc_map_t map; int dev_gindex; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_init_rxdma_channels")); if (!isLDOMguest(nxgep)) { if (nxge_rxdma_hw_start_common(nxgep) != NXGE_OK) { cmn_err(CE_NOTE, "hw_start_common"); return (NXGE_ERROR); } } /* * NXGE_LOGICAL_GROUP_MAX > NXGE_MAX_RDC_GROUPS (8) * We only have 8 hardware RDC tables, but we may have * up to 16 logical (software-defined) groups of RDCS, * if we make use of layer 3 & 4 hardware classification. */ for (i = 0, count = 0; i < NXGE_LOGICAL_GROUP_MAX; i++) { if ((1 << i) & set->lg.map) { group = set->group[i]; dev_gindex = nxgep->pt_config.hw_config.def_mac_rxdma_grpid + i; map = nxgep->pt_config.rdc_grps[dev_gindex].map; for (channel = 0; channel < NXGE_MAX_RDCS; channel++) { if ((1 << channel) & map) { if ((nxge_grp_dc_add(nxgep, group, VP_BOUND_RX, channel))) goto init_rxdma_channels_exit; } } } if (++count == set->lg.count) break; } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_init_rxdma_channels")); return (NXGE_OK); init_rxdma_channels_exit: for (i = 0, count = 0; i < NXGE_LOGICAL_GROUP_MAX; i++) { if ((1 << i) & set->lg.map) { group = set->group[i]; dev_gindex = nxgep->pt_config.hw_config.def_mac_rxdma_grpid + i; map = nxgep->pt_config.rdc_grps[dev_gindex].map; for (channel = 0; channel < NXGE_MAX_RDCS; channel++) { if ((1 << channel) & map) { nxge_grp_dc_remove(nxgep, VP_BOUND_RX, channel); } } } if (++count == set->lg.count) break; } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_init_rxdma_channels")); return (NXGE_ERROR); } nxge_status_t nxge_init_rxdma_channel(p_nxge_t nxge, int channel) { nxge_status_t status; NXGE_DEBUG_MSG((nxge, MEM2_CTL, "==> nxge_init_rxdma_channel")); status = nxge_map_rxdma(nxge, channel); if (status != NXGE_OK) { NXGE_ERROR_MSG((nxge, NXGE_ERR_CTL, "<== nxge_init_rxdma: status 0x%x", status)); return (status); } #if defined(sun4v) if (isLDOMguest(nxge)) { /* set rcr_ring */ p_rx_rcr_ring_t ring = nxge->rx_rcr_rings->rcr_rings[channel]; status = nxge_hio_rxdma_bind_intr(nxge, ring, channel); if (status != NXGE_OK) { nxge_unmap_rxdma(nxge, channel); return (status); } } #endif status = nxge_rxdma_hw_start(nxge, channel); if (status != NXGE_OK) { nxge_unmap_rxdma(nxge, channel); } if (!nxge->statsp->rdc_ksp[channel]) nxge_setup_rdc_kstats(nxge, channel); NXGE_DEBUG_MSG((nxge, MEM2_CTL, "<== nxge_init_rxdma_channel: status 0x%x", status)); return (status); } void nxge_uninit_rxdma_channels(p_nxge_t nxgep) { nxge_grp_set_t *set = &nxgep->rx_set; int rdc; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_uninit_rxdma_channels")); if (set->owned.map == 0) { NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "nxge_uninit_rxdma_channels: no channels")); return; } for (rdc = 0; rdc < NXGE_MAX_RDCS; rdc++) { if ((1 << rdc) & set->owned.map) { nxge_grp_dc_remove(nxgep, VP_BOUND_RX, rdc); } } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_uninit_rxdma_channels")); } void nxge_uninit_rxdma_channel(p_nxge_t nxgep, int channel) { NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_uninit_rxdma_channel")); if (nxgep->statsp->rdc_ksp[channel]) { kstat_delete(nxgep->statsp->rdc_ksp[channel]); nxgep->statsp->rdc_ksp[channel] = 0; } nxge_rxdma_hw_stop(nxgep, channel); nxge_unmap_rxdma(nxgep, channel); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_uinit_rxdma_channel")); } nxge_status_t nxge_reset_rxdma_channel(p_nxge_t nxgep, uint16_t channel) { npi_handle_t handle; npi_status_t rs = NPI_SUCCESS; nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, DMA_CTL, "==> nxge_reset_rxdma_channel")); handle = NXGE_DEV_NPI_HANDLE(nxgep); rs = npi_rxdma_cfg_rdc_reset(handle, channel); if (rs != NPI_SUCCESS) { status = NXGE_ERROR | rs; } NXGE_DEBUG_MSG((nxgep, DMA_CTL, "<== nxge_reset_rxdma_channel")); return (status); } void nxge_rxdma_regs_dump_channels(p_nxge_t nxgep) { nxge_grp_set_t *set = &nxgep->rx_set; int rdc; NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rxdma_regs_dump_channels")); if (!isLDOMguest(nxgep)) { npi_handle_t handle = NXGE_DEV_NPI_HANDLE(nxgep); (void) npi_rxdma_dump_fzc_regs(handle); } if (nxgep->rx_rbr_rings == 0 || nxgep->rx_rbr_rings->rbr_rings == 0) { NXGE_DEBUG_MSG((nxgep, TX_CTL, "nxge_rxdma_regs_dump_channels: " "NULL ring pointer(s)")); return; } if (set->owned.map == 0) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "nxge_rxdma_regs_dump_channels: no channels")); return; } for (rdc = 0; rdc < NXGE_MAX_RDCS; rdc++) { if ((1 << rdc) & set->owned.map) { rx_rbr_ring_t *ring = nxgep->rx_rbr_rings->rbr_rings[rdc]; if (ring) { (void) nxge_dump_rxdma_channel(nxgep, rdc); } } } NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rxdma_regs_dump")); } nxge_status_t nxge_dump_rxdma_channel(p_nxge_t nxgep, uint8_t channel) { npi_handle_t handle; npi_status_t rs = NPI_SUCCESS; nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, DMA_CTL, "==> nxge_dump_rxdma_channel")); handle = NXGE_DEV_NPI_HANDLE(nxgep); rs = npi_rxdma_dump_rdc_regs(handle, channel); if (rs != NPI_SUCCESS) { status = NXGE_ERROR | rs; } NXGE_DEBUG_MSG((nxgep, DMA_CTL, "<== nxge_dump_rxdma_channel")); return (status); } nxge_status_t nxge_init_rxdma_channel_event_mask(p_nxge_t nxgep, uint16_t channel, p_rx_dma_ent_msk_t mask_p) { npi_handle_t handle; npi_status_t rs = NPI_SUCCESS; nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, DMA_CTL, "<== nxge_init_rxdma_channel_event_mask")); handle = NXGE_DEV_NPI_HANDLE(nxgep); rs = npi_rxdma_event_mask(handle, OP_SET, channel, mask_p); if (rs != NPI_SUCCESS) { status = NXGE_ERROR | rs; } return (status); } nxge_status_t nxge_init_rxdma_channel_cntl_stat(p_nxge_t nxgep, uint16_t channel, p_rx_dma_ctl_stat_t cs_p) { npi_handle_t handle; npi_status_t rs = NPI_SUCCESS; nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, DMA_CTL, "<== nxge_init_rxdma_channel_cntl_stat")); handle = NXGE_DEV_NPI_HANDLE(nxgep); rs = npi_rxdma_control_status(handle, OP_SET, channel, cs_p); if (rs != NPI_SUCCESS) { status = NXGE_ERROR | rs; } return (status); } /* * nxge_rxdma_cfg_rdcgrp_default_rdc * * Set the default RDC for an RDC Group (Table) * * Arguments: * nxgep * rdcgrp The group to modify * rdc The new default RDC. * * Notes: * * NPI/NXGE function calls: * npi_rxdma_cfg_rdc_table_default_rdc() * * Registers accessed: * RDC_TBL_REG: FZC_ZCP + 0x10000 * * Context: * Service domain */ nxge_status_t nxge_rxdma_cfg_rdcgrp_default_rdc( p_nxge_t nxgep, uint8_t rdcgrp, uint8_t rdc) { npi_handle_t handle; npi_status_t rs = NPI_SUCCESS; p_nxge_dma_pt_cfg_t p_dma_cfgp; p_nxge_rdc_grp_t rdc_grp_p; uint8_t actual_rdcgrp, actual_rdc; NXGE_DEBUG_MSG((nxgep, RX2_CTL, " ==> nxge_rxdma_cfg_rdcgrp_default_rdc")); p_dma_cfgp = (p_nxge_dma_pt_cfg_t)&nxgep->pt_config; handle = NXGE_DEV_NPI_HANDLE(nxgep); /* * This has to be rewritten. Do we even allow this anymore? */ rdc_grp_p = &p_dma_cfgp->rdc_grps[rdcgrp]; RDC_MAP_IN(rdc_grp_p->map, rdc); rdc_grp_p->def_rdc = rdc; actual_rdcgrp = NXGE_ACTUAL_RDCGRP(nxgep, rdcgrp); actual_rdc = NXGE_ACTUAL_RDC(nxgep, rdc); rs = npi_rxdma_cfg_rdc_table_default_rdc( handle, actual_rdcgrp, actual_rdc); if (rs != NPI_SUCCESS) { return (NXGE_ERROR | rs); } NXGE_DEBUG_MSG((nxgep, RX2_CTL, " <== nxge_rxdma_cfg_rdcgrp_default_rdc")); return (NXGE_OK); } nxge_status_t nxge_rxdma_cfg_port_default_rdc(p_nxge_t nxgep, uint8_t port, uint8_t rdc) { npi_handle_t handle; uint8_t actual_rdc; npi_status_t rs = NPI_SUCCESS; NXGE_DEBUG_MSG((nxgep, RX2_CTL, " ==> nxge_rxdma_cfg_port_default_rdc")); handle = NXGE_DEV_NPI_HANDLE(nxgep); actual_rdc = rdc; /* XXX Hack! */ rs = npi_rxdma_cfg_default_port_rdc(handle, port, actual_rdc); if (rs != NPI_SUCCESS) { return (NXGE_ERROR | rs); } NXGE_DEBUG_MSG((nxgep, RX2_CTL, " <== nxge_rxdma_cfg_port_default_rdc")); return (NXGE_OK); } nxge_status_t nxge_rxdma_cfg_rcr_threshold(p_nxge_t nxgep, uint8_t channel, uint16_t pkts) { npi_status_t rs = NPI_SUCCESS; npi_handle_t handle; NXGE_DEBUG_MSG((nxgep, RX2_CTL, " ==> nxge_rxdma_cfg_rcr_threshold")); handle = NXGE_DEV_NPI_HANDLE(nxgep); rs = npi_rxdma_cfg_rdc_rcr_threshold(handle, channel, pkts); if (rs != NPI_SUCCESS) { return (NXGE_ERROR | rs); } NXGE_DEBUG_MSG((nxgep, RX2_CTL, " <== nxge_rxdma_cfg_rcr_threshold")); return (NXGE_OK); } nxge_status_t nxge_rxdma_cfg_rcr_timeout(p_nxge_t nxgep, uint8_t channel, uint16_t tout, uint8_t enable) { npi_status_t rs = NPI_SUCCESS; npi_handle_t handle; NXGE_DEBUG_MSG((nxgep, RX2_CTL, " ==> nxge_rxdma_cfg_rcr_timeout")); handle = NXGE_DEV_NPI_HANDLE(nxgep); if (enable == 0) { rs = npi_rxdma_cfg_rdc_rcr_timeout_disable(handle, channel); } else { rs = npi_rxdma_cfg_rdc_rcr_timeout(handle, channel, tout); } if (rs != NPI_SUCCESS) { return (NXGE_ERROR | rs); } NXGE_DEBUG_MSG((nxgep, RX2_CTL, " <== nxge_rxdma_cfg_rcr_timeout")); return (NXGE_OK); } nxge_status_t nxge_enable_rxdma_channel(p_nxge_t nxgep, uint16_t channel, p_rx_rbr_ring_t rbr_p, p_rx_rcr_ring_t rcr_p, p_rx_mbox_t mbox_p) { npi_handle_t handle; rdc_desc_cfg_t rdc_desc; p_rcrcfig_b_t cfgb_p; npi_status_t rs = NPI_SUCCESS; NXGE_DEBUG_MSG((nxgep, DMA_CTL, "==> nxge_enable_rxdma_channel")); handle = NXGE_DEV_NPI_HANDLE(nxgep); /* * Use configuration data composed at init time. * Write to hardware the receive ring configurations. */ rdc_desc.mbox_enable = 1; rdc_desc.mbox_addr = mbox_p->mbox_addr; NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_enable_rxdma_channel: mboxp $%p($%p)", mbox_p->mbox_addr, rdc_desc.mbox_addr)); rdc_desc.rbr_len = rbr_p->rbb_max; rdc_desc.rbr_addr = rbr_p->rbr_addr; switch (nxgep->rx_bksize_code) { case RBR_BKSIZE_4K: rdc_desc.page_size = SIZE_4KB; break; case RBR_BKSIZE_8K: rdc_desc.page_size = SIZE_8KB; break; case RBR_BKSIZE_16K: rdc_desc.page_size = SIZE_16KB; break; case RBR_BKSIZE_32K: rdc_desc.page_size = SIZE_32KB; break; } rdc_desc.size0 = rbr_p->npi_pkt_buf_size0; rdc_desc.valid0 = 1; rdc_desc.size1 = rbr_p->npi_pkt_buf_size1; rdc_desc.valid1 = 1; rdc_desc.size2 = rbr_p->npi_pkt_buf_size2; rdc_desc.valid2 = 1; rdc_desc.full_hdr = rcr_p->full_hdr_flag; rdc_desc.offset = rcr_p->sw_priv_hdr_len; rdc_desc.rcr_len = rcr_p->comp_size; rdc_desc.rcr_addr = rcr_p->rcr_addr; cfgb_p = &(rcr_p->rcr_cfgb); rdc_desc.rcr_threshold = cfgb_p->bits.ldw.pthres; /* For now, disable this timeout in a guest domain. */ if (isLDOMguest(nxgep)) { rdc_desc.rcr_timeout = 0; rdc_desc.rcr_timeout_enable = 0; } else { rdc_desc.rcr_timeout = cfgb_p->bits.ldw.timeout; rdc_desc.rcr_timeout_enable = cfgb_p->bits.ldw.entout; } NXGE_DEBUG_MSG((nxgep, DMA_CTL, "==> nxge_enable_rxdma_channel: " "rbr_len qlen %d pagesize code %d rcr_len %d", rdc_desc.rbr_len, rdc_desc.page_size, rdc_desc.rcr_len)); NXGE_DEBUG_MSG((nxgep, DMA_CTL, "==> nxge_enable_rxdma_channel: " "size 0 %d size 1 %d size 2 %d", rbr_p->npi_pkt_buf_size0, rbr_p->npi_pkt_buf_size1, rbr_p->npi_pkt_buf_size2)); if (nxgep->niu_hw_type == NIU_HW_TYPE_RF) rs = npi_rxdma_cfg_rdc_ring(handle, rbr_p->rdc, &rdc_desc, B_TRUE); else rs = npi_rxdma_cfg_rdc_ring(handle, rbr_p->rdc, &rdc_desc, B_FALSE); if (rs != NPI_SUCCESS) { return (NXGE_ERROR | rs); } /* * Enable the timeout and threshold. */ rs = npi_rxdma_cfg_rdc_rcr_threshold(handle, channel, rdc_desc.rcr_threshold); if (rs != NPI_SUCCESS) { return (NXGE_ERROR | rs); } rs = npi_rxdma_cfg_rdc_rcr_timeout(handle, channel, rdc_desc.rcr_timeout); if (rs != NPI_SUCCESS) { return (NXGE_ERROR | rs); } if (!isLDOMguest(nxgep)) { /* Enable the DMA */ rs = npi_rxdma_cfg_rdc_enable(handle, channel); if (rs != NPI_SUCCESS) { return (NXGE_ERROR | rs); } } /* Kick the DMA engine. */ npi_rxdma_rdc_rbr_kick(handle, channel, rbr_p->rbb_max); if (!isLDOMguest(nxgep)) { /* Clear the rbr empty bit */ (void) npi_rxdma_channel_rbr_empty_clear(handle, channel); } NXGE_DEBUG_MSG((nxgep, DMA_CTL, "<== nxge_enable_rxdma_channel")); return (NXGE_OK); } nxge_status_t nxge_disable_rxdma_channel(p_nxge_t nxgep, uint16_t channel) { npi_handle_t handle; npi_status_t rs = NPI_SUCCESS; NXGE_DEBUG_MSG((nxgep, DMA_CTL, "==> nxge_disable_rxdma_channel")); handle = NXGE_DEV_NPI_HANDLE(nxgep); /* disable the DMA */ rs = npi_rxdma_cfg_rdc_disable(handle, channel); if (rs != NPI_SUCCESS) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_disable_rxdma_channel:failed (0x%x)", rs)); return (NXGE_ERROR | rs); } NXGE_DEBUG_MSG((nxgep, DMA_CTL, "<== nxge_disable_rxdma_channel")); return (NXGE_OK); } nxge_status_t nxge_rxdma_channel_rcrflush(p_nxge_t nxgep, uint8_t channel) { npi_handle_t handle; nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, DMA_CTL, "<== nxge_init_rxdma_channel_rcrflush")); handle = NXGE_DEV_NPI_HANDLE(nxgep); npi_rxdma_rdc_rcr_flush(handle, channel); NXGE_DEBUG_MSG((nxgep, DMA_CTL, "<== nxge_init_rxdma_channel_rcrflsh")); return (status); } #define MID_INDEX(l, r) ((r + l + 1) >> 1) #define TO_LEFT -1 #define TO_RIGHT 1 #define BOTH_RIGHT (TO_RIGHT + TO_RIGHT) #define BOTH_LEFT (TO_LEFT + TO_LEFT) #define IN_MIDDLE (TO_RIGHT + TO_LEFT) #define NO_HINT 0xffffffff /*ARGSUSED*/ nxge_status_t nxge_rxbuf_pp_to_vp(p_nxge_t nxgep, p_rx_rbr_ring_t rbr_p, uint8_t pktbufsz_type, uint64_t *pkt_buf_addr_pp, uint64_t **pkt_buf_addr_p, uint32_t *bufoffset, uint32_t *msg_index) { int bufsize; uint64_t pktbuf_pp; uint64_t dvma_addr; rxring_info_t *ring_info; int base_side, end_side; int r_index, l_index, anchor_index; int found, search_done; uint32_t offset, chunk_size, block_size, page_size_mask; uint32_t chunk_index, block_index, total_index; int max_iterations, iteration; rxbuf_index_info_t *bufinfo; NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_rxbuf_pp_to_vp")); NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_rxbuf_pp_to_vp: buf_pp $%p btype %d", pkt_buf_addr_pp, pktbufsz_type)); #if defined(__i386) pktbuf_pp = (uint64_t)(uint32_t)pkt_buf_addr_pp; #else pktbuf_pp = (uint64_t)pkt_buf_addr_pp; #endif switch (pktbufsz_type) { case 0: bufsize = rbr_p->pkt_buf_size0; break; case 1: bufsize = rbr_p->pkt_buf_size1; break; case 2: bufsize = rbr_p->pkt_buf_size2; break; case RCR_SINGLE_BLOCK: bufsize = 0; anchor_index = 0; break; default: return (NXGE_ERROR); } if (rbr_p->num_blocks == 1) { anchor_index = 0; ring_info = rbr_p->ring_info; bufinfo = (rxbuf_index_info_t *)ring_info->buffer; NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_rxbuf_pp_to_vp: (found, 1 block) " "buf_pp $%p btype %d anchor_index %d " "bufinfo $%p", pkt_buf_addr_pp, pktbufsz_type, anchor_index, bufinfo)); goto found_index; } NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_rxbuf_pp_to_vp: " "buf_pp $%p btype %d anchor_index %d", pkt_buf_addr_pp, pktbufsz_type, anchor_index)); ring_info = rbr_p->ring_info; found = B_FALSE; bufinfo = (rxbuf_index_info_t *)ring_info->buffer; iteration = 0; max_iterations = ring_info->max_iterations; /* * First check if this block has been seen * recently. This is indicated by a hint which * is initialized when the first buffer of the block * is seen. The hint is reset when the last buffer of * the block has been processed. * As three block sizes are supported, three hints * are kept. The idea behind the hints is that once * the hardware uses a block for a buffer of that * size, it will use it exclusively for that size * and will use it until it is exhausted. It is assumed * that there would a single block being used for the same * buffer sizes at any given time. */ if (ring_info->hint[pktbufsz_type] != NO_HINT) { anchor_index = ring_info->hint[pktbufsz_type]; dvma_addr = bufinfo[anchor_index].dvma_addr; chunk_size = bufinfo[anchor_index].buf_size; if ((pktbuf_pp >= dvma_addr) && (pktbuf_pp < (dvma_addr + chunk_size))) { found = B_TRUE; /* * check if this is the last buffer in the block * If so, then reset the hint for the size; */ if ((pktbuf_pp + bufsize) >= (dvma_addr + chunk_size)) ring_info->hint[pktbufsz_type] = NO_HINT; } } if (found == B_FALSE) { NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_rxbuf_pp_to_vp: (!found)" "buf_pp $%p btype %d anchor_index %d", pkt_buf_addr_pp, pktbufsz_type, anchor_index)); /* * This is the first buffer of the block of this * size. Need to search the whole information * array. * the search algorithm uses a binary tree search * algorithm. It assumes that the information is * already sorted with increasing order * info[0] < info[1] < info[2] .... < info[n-1] * where n is the size of the information array */ r_index = rbr_p->num_blocks - 1; l_index = 0; search_done = B_FALSE; anchor_index = MID_INDEX(r_index, l_index); while (search_done == B_FALSE) { if ((r_index == l_index) || (iteration >= max_iterations)) search_done = B_TRUE; end_side = TO_RIGHT; /* to the right */ base_side = TO_LEFT; /* to the left */ /* read the DVMA address information and sort it */ dvma_addr = bufinfo[anchor_index].dvma_addr; chunk_size = bufinfo[anchor_index].buf_size; NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_rxbuf_pp_to_vp: (searching)" "buf_pp $%p btype %d " "anchor_index %d chunk_size %d dvmaaddr $%p", pkt_buf_addr_pp, pktbufsz_type, anchor_index, chunk_size, dvma_addr)); if (pktbuf_pp >= dvma_addr) base_side = TO_RIGHT; /* to the right */ if (pktbuf_pp < (dvma_addr + chunk_size)) end_side = TO_LEFT; /* to the left */ switch (base_side + end_side) { case IN_MIDDLE: /* found */ found = B_TRUE; search_done = B_TRUE; if ((pktbuf_pp + bufsize) < (dvma_addr + chunk_size)) ring_info->hint[pktbufsz_type] = bufinfo[anchor_index].buf_index; break; case BOTH_RIGHT: /* not found: go to the right */ l_index = anchor_index + 1; anchor_index = MID_INDEX(r_index, l_index); break; case BOTH_LEFT: /* not found: go to the left */ r_index = anchor_index - 1; anchor_index = MID_INDEX(r_index, l_index); break; default: /* should not come here */ return (NXGE_ERROR); } iteration++; } NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_rxbuf_pp_to_vp: (search done)" "buf_pp $%p btype %d anchor_index %d", pkt_buf_addr_pp, pktbufsz_type, anchor_index)); } if (found == B_FALSE) { NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_rxbuf_pp_to_vp: (search failed)" "buf_pp $%p btype %d anchor_index %d", pkt_buf_addr_pp, pktbufsz_type, anchor_index)); return (NXGE_ERROR); } found_index: NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_rxbuf_pp_to_vp: (FOUND1)" "buf_pp $%p btype %d bufsize %d anchor_index %d", pkt_buf_addr_pp, pktbufsz_type, bufsize, anchor_index)); /* index of the first block in this chunk */ chunk_index = bufinfo[anchor_index].start_index; dvma_addr = bufinfo[anchor_index].dvma_addr; page_size_mask = ring_info->block_size_mask; NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_rxbuf_pp_to_vp: (FOUND3), get chunk)" "buf_pp $%p btype %d bufsize %d " "anchor_index %d chunk_index %d dvma $%p", pkt_buf_addr_pp, pktbufsz_type, bufsize, anchor_index, chunk_index, dvma_addr)); offset = pktbuf_pp - dvma_addr; /* offset within the chunk */ block_size = rbr_p->block_size; /* System block(page) size */ NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_rxbuf_pp_to_vp: (FOUND4), get chunk)" "buf_pp $%p btype %d bufsize %d " "anchor_index %d chunk_index %d dvma $%p " "offset %d block_size %d", pkt_buf_addr_pp, pktbufsz_type, bufsize, anchor_index, chunk_index, dvma_addr, offset, block_size)); NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> getting total index")); block_index = (offset / block_size); /* index within chunk */ total_index = chunk_index + block_index; NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_rxbuf_pp_to_vp: " "total_index %d dvma_addr $%p " "offset %d block_size %d " "block_index %d ", total_index, dvma_addr, offset, block_size, block_index)); #if defined(__i386) *pkt_buf_addr_p = (uint64_t *)((uint32_t)bufinfo[anchor_index].kaddr + (uint32_t)offset); #else *pkt_buf_addr_p = (uint64_t *)((uint64_t)bufinfo[anchor_index].kaddr + (uint64_t)offset); #endif NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_rxbuf_pp_to_vp: " "total_index %d dvma_addr $%p " "offset %d block_size %d " "block_index %d " "*pkt_buf_addr_p $%p", total_index, dvma_addr, offset, block_size, block_index, *pkt_buf_addr_p)); *msg_index = total_index; *bufoffset = (offset & page_size_mask); NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_rxbuf_pp_to_vp: get msg index: " "msg_index %d bufoffset_index %d", *msg_index, *bufoffset)); NXGE_DEBUG_MSG((nxgep, RX2_CTL, "<== nxge_rxbuf_pp_to_vp")); return (NXGE_OK); } /* * used by quick sort (qsort) function * to perform comparison */ static int nxge_sort_compare(const void *p1, const void *p2) { rxbuf_index_info_t *a, *b; a = (rxbuf_index_info_t *)p1; b = (rxbuf_index_info_t *)p2; if (a->dvma_addr > b->dvma_addr) return (1); if (a->dvma_addr < b->dvma_addr) return (-1); return (0); } /* * grabbed this sort implementation from common/syscall/avl.c * */ /* * Generic shellsort, from K&R (1st ed, p 58.), somewhat modified. * v = Ptr to array/vector of objs * n = # objs in the array * s = size of each obj (must be multiples of a word size) * f = ptr to function to compare two objs * returns (-1 = less than, 0 = equal, 1 = greater than */ void nxge_ksort(caddr_t v, int n, int s, int (*f)()) { int g, i, j, ii; unsigned int *p1, *p2; unsigned int tmp; /* No work to do */ if (v == NULL || n <= 1) return; /* Sanity check on arguments */ ASSERT(((uintptr_t)v & 0x3) == 0 && (s & 0x3) == 0); ASSERT(s > 0); for (g = n / 2; g > 0; g /= 2) { for (i = g; i < n; i++) { for (j = i - g; j >= 0 && (*f)(v + j * s, v + (j + g) * s) == 1; j -= g) { p1 = (unsigned *)(v + j * s); p2 = (unsigned *)(v + (j + g) * s); for (ii = 0; ii < s / 4; ii++) { tmp = *p1; *p1++ = *p2; *p2++ = tmp; } } } } } /* * Initialize data structures required for rxdma * buffer dvma->vmem address lookup */ /*ARGSUSED*/ static nxge_status_t nxge_rxbuf_index_info_init(p_nxge_t nxgep, p_rx_rbr_ring_t rbrp) { int index; rxring_info_t *ring_info; int max_iteration = 0, max_index = 0; NXGE_DEBUG_MSG((nxgep, DMA_CTL, "==> nxge_rxbuf_index_info_init")); ring_info = rbrp->ring_info; ring_info->hint[0] = NO_HINT; ring_info->hint[1] = NO_HINT; ring_info->hint[2] = NO_HINT; max_index = rbrp->num_blocks; /* read the DVMA address information and sort it */ /* do init of the information array */ NXGE_DEBUG_MSG((nxgep, DMA2_CTL, " nxge_rxbuf_index_info_init Sort ptrs")); /* sort the array */ nxge_ksort((void *)ring_info->buffer, max_index, sizeof (rxbuf_index_info_t), nxge_sort_compare); for (index = 0; index < max_index; index++) { NXGE_DEBUG_MSG((nxgep, DMA2_CTL, " nxge_rxbuf_index_info_init: sorted chunk %d " " ioaddr $%p kaddr $%p size %x", index, ring_info->buffer[index].dvma_addr, ring_info->buffer[index].kaddr, ring_info->buffer[index].buf_size)); } max_iteration = 0; while (max_index >= (1ULL << max_iteration)) max_iteration++; ring_info->max_iterations = max_iteration + 1; NXGE_DEBUG_MSG((nxgep, DMA2_CTL, " nxge_rxbuf_index_info_init Find max iter %d", ring_info->max_iterations)); NXGE_DEBUG_MSG((nxgep, DMA_CTL, "<== nxge_rxbuf_index_info_init")); return (NXGE_OK); } /* ARGSUSED */ void nxge_dump_rcr_entry(p_nxge_t nxgep, p_rcr_entry_t entry_p) { #ifdef NXGE_DEBUG uint32_t bptr; uint64_t pp; bptr = entry_p->bits.hdw.pkt_buf_addr; NXGE_DEBUG_MSG((nxgep, RX_CTL, "\trcr entry $%p " "\trcr entry 0x%0llx " "\trcr entry 0x%08x " "\trcr entry 0x%08x " "\tvalue 0x%0llx\n" "\tmulti = %d\n" "\tpkt_type = 0x%x\n" "\tzero_copy = %d\n" "\tnoport = %d\n" "\tpromis = %d\n" "\terror = 0x%04x\n" "\tdcf_err = 0x%01x\n" "\tl2_len = %d\n" "\tpktbufsize = %d\n" "\tpkt_buf_addr = $%p\n" "\tpkt_buf_addr (<< 6) = $%p\n", entry_p, *(int64_t *)entry_p, *(int32_t *)entry_p, *(int32_t *)((char *)entry_p + 32), entry_p->value, entry_p->bits.hdw.multi, entry_p->bits.hdw.pkt_type, entry_p->bits.hdw.zero_copy, entry_p->bits.hdw.noport, entry_p->bits.hdw.promis, entry_p->bits.hdw.error, entry_p->bits.hdw.dcf_err, entry_p->bits.hdw.l2_len, entry_p->bits.hdw.pktbufsz, bptr, entry_p->bits.ldw.pkt_buf_addr)); pp = (entry_p->value & RCR_PKT_BUF_ADDR_MASK) << RCR_PKT_BUF_ADDR_SHIFT; NXGE_DEBUG_MSG((nxgep, RX_CTL, "rcr pp 0x%llx l2 len %d", pp, (*(int64_t *)entry_p >> 40) & 0x3fff)); #endif } void nxge_rxdma_regs_dump(p_nxge_t nxgep, int rdc) { npi_handle_t handle; rbr_stat_t rbr_stat; addr44_t hd_addr; addr44_t tail_addr; uint16_t qlen; NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rxdma_regs_dump: rdc channel %d", rdc)); handle = NXGE_DEV_NPI_HANDLE(nxgep); /* RBR head */ hd_addr.addr = 0; (void) npi_rxdma_rdc_rbr_head_get(handle, rdc, &hd_addr); #if defined(__i386) printf("nxge_rxdma_regs_dump: got hdptr $%p \n", (void *)(uint32_t)hd_addr.addr); #else printf("nxge_rxdma_regs_dump: got hdptr $%p \n", (void *)hd_addr.addr); #endif /* RBR stats */ (void) npi_rxdma_rdc_rbr_stat_get(handle, rdc, &rbr_stat); printf("nxge_rxdma_regs_dump: rbr len %d \n", rbr_stat.bits.ldw.qlen); /* RCR tail */ tail_addr.addr = 0; (void) npi_rxdma_rdc_rcr_tail_get(handle, rdc, &tail_addr); #if defined(__i386) printf("nxge_rxdma_regs_dump: got tail ptr $%p \n", (void *)(uint32_t)tail_addr.addr); #else printf("nxge_rxdma_regs_dump: got tail ptr $%p \n", (void *)tail_addr.addr); #endif /* RCR qlen */ (void) npi_rxdma_rdc_rcr_qlen_get(handle, rdc, &qlen); printf("nxge_rxdma_regs_dump: rcr len %x \n", qlen); NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rxdma_regs_dump: rdc rdc %d", rdc)); } nxge_status_t nxge_rxdma_hw_mode(p_nxge_t nxgep, boolean_t enable) { nxge_grp_set_t *set = &nxgep->rx_set; nxge_status_t status; npi_status_t rs; int rdc; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_hw_mode: mode %d", enable)); if (!(nxgep->drv_state & STATE_HW_INITIALIZED)) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rxdma_mode: not initialized")); return (NXGE_ERROR); } if (nxgep->rx_rbr_rings == 0 || nxgep->rx_rbr_rings->rbr_rings == 0) { NXGE_DEBUG_MSG((nxgep, TX_CTL, "<== nxge_tx_port_fatal_err_recover: " "NULL ring pointer(s)")); return (NXGE_ERROR); } if (set->owned.map == 0) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "nxge_rxdma_regs_dump_channels: no channels")); return (NULL); } for (rdc = 0; rdc < NXGE_MAX_RDCS; rdc++) { if ((1 << rdc) & set->owned.map) { rx_rbr_ring_t *ring = nxgep->rx_rbr_rings->rbr_rings[rdc]; npi_handle_t handle = NXGE_DEV_NPI_HANDLE(nxgep); if (ring) { if (enable) { NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_hw_mode: " "channel %d (enable)", rdc)); rs = npi_rxdma_cfg_rdc_enable (handle, rdc); } else { NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_hw_mode: " "channel %d disable)", rdc)); rs = npi_rxdma_cfg_rdc_disable (handle, rdc); } } } } status = ((rs == NPI_SUCCESS) ? NXGE_OK : NXGE_ERROR | rs); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_rxdma_hw_mode: status 0x%x", status)); return (status); } void nxge_rxdma_enable_channel(p_nxge_t nxgep, uint16_t channel) { npi_handle_t handle; NXGE_DEBUG_MSG((nxgep, DMA_CTL, "==> nxge_rxdma_enable_channel: channel %d", channel)); handle = NXGE_DEV_NPI_HANDLE(nxgep); (void) npi_rxdma_cfg_rdc_enable(handle, channel); NXGE_DEBUG_MSG((nxgep, DMA_CTL, "<== nxge_rxdma_enable_channel")); } void nxge_rxdma_disable_channel(p_nxge_t nxgep, uint16_t channel) { npi_handle_t handle; NXGE_DEBUG_MSG((nxgep, DMA_CTL, "==> nxge_rxdma_disable_channel: channel %d", channel)); handle = NXGE_DEV_NPI_HANDLE(nxgep); (void) npi_rxdma_cfg_rdc_disable(handle, channel); NXGE_DEBUG_MSG((nxgep, DMA_CTL, "<== nxge_rxdma_disable_channel")); } void nxge_hw_start_rx(p_nxge_t nxgep) { NXGE_DEBUG_MSG((nxgep, DDI_CTL, "==> nxge_hw_start_rx")); (void) nxge_rxdma_hw_mode(nxgep, NXGE_DMA_START); (void) nxge_rx_mac_enable(nxgep); NXGE_DEBUG_MSG((nxgep, DDI_CTL, "<== nxge_hw_start_rx")); } /*ARGSUSED*/ void nxge_fixup_rxdma_rings(p_nxge_t nxgep) { nxge_grp_set_t *set = &nxgep->rx_set; int rdc; NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_fixup_rxdma_rings")); if (nxgep->rx_rbr_rings == 0 || nxgep->rx_rbr_rings->rbr_rings == 0) { NXGE_DEBUG_MSG((nxgep, TX_CTL, "<== nxge_tx_port_fatal_err_recover: " "NULL ring pointer(s)")); return; } if (set->owned.map == 0) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "nxge_rxdma_regs_dump_channels: no channels")); return; } for (rdc = 0; rdc < NXGE_MAX_RDCS; rdc++) { if ((1 << rdc) & set->owned.map) { rx_rbr_ring_t *ring = nxgep->rx_rbr_rings->rbr_rings[rdc]; if (ring) { nxge_rxdma_hw_stop(nxgep, rdc); NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_fixup_rxdma_rings: " "channel %d ring $%px", rdc, ring)); (void) nxge_rxdma_fix_channel(nxgep, rdc); } } } NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_fixup_rxdma_rings")); } void nxge_rxdma_fix_channel(p_nxge_t nxgep, uint16_t channel) { int ndmas; p_rx_rbr_rings_t rx_rbr_rings; p_rx_rbr_ring_t *rbr_rings; p_rx_rcr_rings_t rx_rcr_rings; p_rx_rcr_ring_t *rcr_rings; p_rx_mbox_areas_t rx_mbox_areas_p; p_rx_mbox_t *rx_mbox_p; p_nxge_dma_pool_t dma_buf_poolp; p_nxge_dma_pool_t dma_cntl_poolp; p_rx_rbr_ring_t rbrp; p_rx_rcr_ring_t rcrp; p_rx_mbox_t mboxp; p_nxge_dma_common_t dmap; nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rxdma_fix_channel")); (void) nxge_rxdma_stop_channel(nxgep, channel); dma_buf_poolp = nxgep->rx_buf_pool_p; dma_cntl_poolp = nxgep->rx_cntl_pool_p; if (!dma_buf_poolp->buf_allocated || !dma_cntl_poolp->buf_allocated) { NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_rxdma_fix_channel: buf not allocated")); return; } ndmas = dma_buf_poolp->ndmas; if (!ndmas) { NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_rxdma_fix_channel: no dma allocated")); return; } rx_rbr_rings = nxgep->rx_rbr_rings; rx_rcr_rings = nxgep->rx_rcr_rings; rbr_rings = rx_rbr_rings->rbr_rings; rcr_rings = rx_rcr_rings->rcr_rings; rx_mbox_areas_p = nxgep->rx_mbox_areas_p; rx_mbox_p = rx_mbox_areas_p->rxmbox_areas; /* Reinitialize the receive block and completion rings */ rbrp = (p_rx_rbr_ring_t)rbr_rings[channel], rcrp = (p_rx_rcr_ring_t)rcr_rings[channel], mboxp = (p_rx_mbox_t)rx_mbox_p[channel]; rbrp->rbr_wr_index = (rbrp->rbb_max - 1); rbrp->rbr_rd_index = 0; rcrp->comp_rd_index = 0; rcrp->comp_wt_index = 0; dmap = (p_nxge_dma_common_t)&rcrp->rcr_desc; bzero((caddr_t)dmap->kaddrp, dmap->alength); status = nxge_rxdma_start_channel(nxgep, channel, rbrp, rcrp, mboxp); if (status != NXGE_OK) { goto nxge_rxdma_fix_channel_fail; } NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rxdma_fix_channel: success (0x%08x)", status)); return; nxge_rxdma_fix_channel_fail: NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rxdma_fix_channel: failed (0x%08x)", status)); } p_rx_rbr_ring_t nxge_rxdma_get_rbr_ring(p_nxge_t nxgep, uint16_t channel) { nxge_grp_set_t *set = &nxgep->rx_set; nxge_channel_t rdc; NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rxdma_get_rbr_ring: channel %d", channel)); if (nxgep->rx_rbr_rings == 0 || nxgep->rx_rbr_rings->rbr_rings == 0) { NXGE_DEBUG_MSG((nxgep, TX_CTL, "<== nxge_rxdma_get_rbr_ring: " "NULL ring pointer(s)")); return (NULL); } if (set->owned.map == 0) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rxdma_get_rbr_ring: no channels")); return (NULL); } for (rdc = 0; rdc < NXGE_MAX_RDCS; rdc++) { if ((1 << rdc) & set->owned.map) { rx_rbr_ring_t *ring = nxgep->rx_rbr_rings->rbr_rings[rdc]; if (ring) { if (channel == ring->rdc) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rxdma_get_rbr_ring: " "channel %d ring $%p", rdc, ring)); return (ring); } } } } NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rxdma_get_rbr_ring: not found")); return (NULL); } p_rx_rcr_ring_t nxge_rxdma_get_rcr_ring(p_nxge_t nxgep, uint16_t channel) { nxge_grp_set_t *set = &nxgep->rx_set; nxge_channel_t rdc; NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rxdma_get_rcr_ring: channel %d", channel)); if (nxgep->rx_rcr_rings == 0 || nxgep->rx_rcr_rings->rcr_rings == 0) { NXGE_DEBUG_MSG((nxgep, TX_CTL, "<== nxge_rxdma_get_rcr_ring: " "NULL ring pointer(s)")); return (NULL); } if (set->owned.map == 0) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rxdma_get_rbr_ring: no channels")); return (NULL); } for (rdc = 0; rdc < NXGE_MAX_RDCS; rdc++) { if ((1 << rdc) & set->owned.map) { rx_rcr_ring_t *ring = nxgep->rx_rcr_rings->rcr_rings[rdc]; if (ring) { if (channel == ring->rdc) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rxdma_get_rcr_ring: " "channel %d ring $%p", rdc, ring)); return (ring); } } } } NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rxdma_get_rcr_ring: not found")); return (NULL); } /* * Static functions start here. */ static p_rx_msg_t nxge_allocb(size_t size, uint32_t pri, p_nxge_dma_common_t dmabuf_p) { p_rx_msg_t nxge_mp = NULL; p_nxge_dma_common_t dmamsg_p; uchar_t *buffer; nxge_mp = KMEM_ZALLOC(sizeof (rx_msg_t), KM_NOSLEEP); if (nxge_mp == NULL) { NXGE_ERROR_MSG((NULL, NXGE_ERR_CTL, "Allocation of a rx msg failed.")); goto nxge_allocb_exit; } nxge_mp->use_buf_pool = B_FALSE; if (dmabuf_p) { nxge_mp->use_buf_pool = B_TRUE; dmamsg_p = (p_nxge_dma_common_t)&nxge_mp->buf_dma; *dmamsg_p = *dmabuf_p; dmamsg_p->nblocks = 1; dmamsg_p->block_size = size; dmamsg_p->alength = size; buffer = (uchar_t *)dmabuf_p->kaddrp; dmabuf_p->kaddrp = (void *) ((char *)dmabuf_p->kaddrp + size); dmabuf_p->ioaddr_pp = (void *) ((char *)dmabuf_p->ioaddr_pp + size); dmabuf_p->alength -= size; dmabuf_p->offset += size; dmabuf_p->dma_cookie.dmac_laddress += size; dmabuf_p->dma_cookie.dmac_size -= size; } else { buffer = KMEM_ALLOC(size, KM_NOSLEEP); if (buffer == NULL) { NXGE_ERROR_MSG((NULL, NXGE_ERR_CTL, "Allocation of a receive page failed.")); goto nxge_allocb_fail1; } } nxge_mp->rx_mblk_p = desballoc(buffer, size, pri, &nxge_mp->freeb); if (nxge_mp->rx_mblk_p == NULL) { NXGE_ERROR_MSG((NULL, NXGE_ERR_CTL, "desballoc failed.")); goto nxge_allocb_fail2; } nxge_mp->buffer = buffer; nxge_mp->block_size = size; nxge_mp->freeb.free_func = (void (*)())nxge_freeb; nxge_mp->freeb.free_arg = (caddr_t)nxge_mp; nxge_mp->ref_cnt = 1; nxge_mp->free = B_TRUE; nxge_mp->rx_use_bcopy = B_FALSE; atomic_inc_32(&nxge_mblks_pending); goto nxge_allocb_exit; nxge_allocb_fail2: if (!nxge_mp->use_buf_pool) { KMEM_FREE(buffer, size); } nxge_allocb_fail1: KMEM_FREE(nxge_mp, sizeof (rx_msg_t)); nxge_mp = NULL; nxge_allocb_exit: return (nxge_mp); } p_mblk_t nxge_dupb(p_rx_msg_t nxge_mp, uint_t offset, size_t size) { p_mblk_t mp; NXGE_DEBUG_MSG((NULL, MEM_CTL, "==> nxge_dupb")); NXGE_DEBUG_MSG((NULL, MEM_CTL, "nxge_mp = $%p " "offset = 0x%08X " "size = 0x%08X", nxge_mp, offset, size)); mp = desballoc(&nxge_mp->buffer[offset], size, 0, &nxge_mp->freeb); if (mp == NULL) { NXGE_DEBUG_MSG((NULL, RX_CTL, "desballoc failed")); goto nxge_dupb_exit; } atomic_inc_32(&nxge_mp->ref_cnt); nxge_dupb_exit: NXGE_DEBUG_MSG((NULL, MEM_CTL, "<== nxge_dupb mp = $%p", nxge_mp)); return (mp); } p_mblk_t nxge_dupb_bcopy(p_rx_msg_t nxge_mp, uint_t offset, size_t size) { p_mblk_t mp; uchar_t *dp; mp = allocb(size + NXGE_RXBUF_EXTRA, 0); if (mp == NULL) { NXGE_DEBUG_MSG((NULL, RX_CTL, "desballoc failed")); goto nxge_dupb_bcopy_exit; } dp = mp->b_rptr = mp->b_rptr + NXGE_RXBUF_EXTRA; bcopy((void *)&nxge_mp->buffer[offset], dp, size); mp->b_wptr = dp + size; nxge_dupb_bcopy_exit: NXGE_DEBUG_MSG((NULL, MEM_CTL, "<== nxge_dupb mp = $%p", nxge_mp)); return (mp); } void nxge_post_page(p_nxge_t nxgep, p_rx_rbr_ring_t rx_rbr_p, p_rx_msg_t rx_msg_p); void nxge_post_page(p_nxge_t nxgep, p_rx_rbr_ring_t rx_rbr_p, p_rx_msg_t rx_msg_p) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_post_page")); /* Reuse this buffer */ rx_msg_p->free = B_FALSE; rx_msg_p->cur_usage_cnt = 0; rx_msg_p->max_usage_cnt = 0; rx_msg_p->pkt_buf_size = 0; if (rx_rbr_p->rbr_use_bcopy) { rx_msg_p->rx_use_bcopy = B_FALSE; atomic_dec_32(&rx_rbr_p->rbr_consumed); } /* * Get the rbr header pointer and its offset index. */ MUTEX_ENTER(&rx_rbr_p->post_lock); rx_rbr_p->rbr_wr_index = ((rx_rbr_p->rbr_wr_index + 1) & rx_rbr_p->rbr_wrap_mask); rx_rbr_p->rbr_desc_vp[rx_rbr_p->rbr_wr_index] = rx_msg_p->shifted_addr; MUTEX_EXIT(&rx_rbr_p->post_lock); npi_rxdma_rdc_rbr_kick(NXGE_DEV_NPI_HANDLE(nxgep), rx_rbr_p->rdc, 1); NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_post_page (channel %d post_next_index %d)", rx_rbr_p->rdc, rx_rbr_p->rbr_wr_index)); NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_post_page")); } void nxge_freeb(p_rx_msg_t rx_msg_p) { size_t size; uchar_t *buffer = NULL; int ref_cnt; boolean_t free_state = B_FALSE; rx_rbr_ring_t *ring = rx_msg_p->rx_rbr_p; NXGE_DEBUG_MSG((NULL, MEM2_CTL, "==> nxge_freeb")); NXGE_DEBUG_MSG((NULL, MEM2_CTL, "nxge_freeb:rx_msg_p = $%p (block pending %d)", rx_msg_p, nxge_mblks_pending)); /* * First we need to get the free state, then * atomic decrement the reference count to prevent * the race condition with the interrupt thread that * is processing a loaned up buffer block. */ free_state = rx_msg_p->free; ref_cnt = atomic_add_32_nv(&rx_msg_p->ref_cnt, -1); if (!ref_cnt) { atomic_dec_32(&nxge_mblks_pending); buffer = rx_msg_p->buffer; size = rx_msg_p->block_size; NXGE_DEBUG_MSG((NULL, MEM2_CTL, "nxge_freeb: " "will free: rx_msg_p = $%p (block pending %d)", rx_msg_p, nxge_mblks_pending)); if (!rx_msg_p->use_buf_pool) { KMEM_FREE(buffer, size); } KMEM_FREE(rx_msg_p, sizeof (rx_msg_t)); if (ring) { /* * Decrement the receive buffer ring's reference * count, too. */ atomic_dec_32(&ring->rbr_ref_cnt); /* * Free the receive buffer ring, if * 1. all the receive buffers have been freed * 2. and we are in the proper state (that is, * we are not UNMAPPING). */ if (ring->rbr_ref_cnt == 0 && ring->rbr_state == RBR_UNMAPPED) { /* * Free receive data buffers, * buffer index information * (rxring_info) and * the message block ring. */ NXGE_DEBUG_MSG((NULL, RX_CTL, "nxge_freeb:rx_msg_p = $%p " "(block pending %d) free buffers", rx_msg_p, nxge_mblks_pending)); nxge_rxdma_databuf_free(ring); if (ring->ring_info) { KMEM_FREE(ring->ring_info, sizeof (rxring_info_t)); } if (ring->rx_msg_ring) { KMEM_FREE(ring->rx_msg_ring, ring->tnblocks * sizeof (p_rx_msg_t)); } KMEM_FREE(ring, sizeof (*ring)); } } return; } /* * Repost buffer. */ if (free_state && (ref_cnt == 1) && ring) { NXGE_DEBUG_MSG((NULL, RX_CTL, "nxge_freeb: post page $%p:", rx_msg_p)); if (ring->rbr_state == RBR_POSTING) nxge_post_page(rx_msg_p->nxgep, ring, rx_msg_p); } NXGE_DEBUG_MSG((NULL, MEM2_CTL, "<== nxge_freeb")); } uint_t nxge_rx_intr(void *arg1, void *arg2) { p_nxge_ldv_t ldvp = (p_nxge_ldv_t)arg1; p_nxge_t nxgep = (p_nxge_t)arg2; p_nxge_ldg_t ldgp; uint8_t channel; npi_handle_t handle; rx_dma_ctl_stat_t cs; p_rx_rcr_ring_t rcrp; mblk_t *mp = NULL; if (ldvp == NULL) { NXGE_DEBUG_MSG((NULL, INT_CTL, "<== nxge_rx_intr: arg2 $%p arg1 $%p", nxgep, ldvp)); return (DDI_INTR_CLAIMED); } if (arg2 == NULL || (void *)ldvp->nxgep != arg2) { nxgep = ldvp->nxgep; } if ((!(nxgep->drv_state & STATE_HW_INITIALIZED)) || (nxgep->nxge_mac_state != NXGE_MAC_STARTED)) { NXGE_DEBUG_MSG((nxgep, INT_CTL, "<== nxge_rx_intr: interface not started or intialized")); return (DDI_INTR_CLAIMED); } NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rx_intr: arg2 $%p arg1 $%p", nxgep, ldvp)); /* * Get the PIO handle. */ handle = NXGE_DEV_NPI_HANDLE(nxgep); /* * Get the ring to enable us to process packets. */ rcrp = nxgep->rx_rcr_rings->rcr_rings[ldvp->vdma_index]; /* * The RCR ring lock must be held when packets * are being processed and the hardware registers are * being read or written to prevent race condition * among the interrupt thread, the polling thread * (will cause fatal errors such as rcrincon bit set) * and the setting of the poll_flag. */ MUTEX_ENTER(&rcrp->lock); /* * Get the control and status for this channel. */ channel = ldvp->channel; ldgp = ldvp->ldgp; if (!isLDOMguest(nxgep) && (!nxgep->rx_channel_started[channel])) { NXGE_DEBUG_MSG((nxgep, INT_CTL, "<== nxge_rx_intr: channel is not started")); /* * We received an interrupt before the ring is started. */ RXDMA_REG_READ64(handle, RX_DMA_CTL_STAT_REG, channel, &cs.value); cs.value &= RX_DMA_CTL_STAT_WR1C; cs.bits.hdw.mex = 1; RXDMA_REG_WRITE64(handle, RX_DMA_CTL_STAT_REG, channel, cs.value); /* * Rearm this logical group if this is a single device * group. */ if (ldgp->nldvs == 1) { if (isLDOMguest(nxgep)) { nxge_hio_ldgimgn(nxgep, ldgp); } else { ldgimgm_t mgm; mgm.value = 0; mgm.bits.ldw.arm = 1; mgm.bits.ldw.timer = ldgp->ldg_timer; NXGE_REG_WR64(handle, LDGIMGN_REG + LDSV_OFFSET(ldgp->ldg), mgm.value); } } MUTEX_EXIT(&rcrp->lock); return (DDI_INTR_CLAIMED); } ASSERT(rcrp->ldgp == ldgp); ASSERT(rcrp->ldvp == ldvp); RXDMA_REG_READ64(handle, RX_DMA_CTL_STAT_REG, channel, &cs.value); NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rx_intr:channel %d " "cs 0x%016llx rcrto 0x%x rcrthres %x", channel, cs.value, cs.bits.hdw.rcrto, cs.bits.hdw.rcrthres)); if (!rcrp->poll_flag) { mp = nxge_rx_pkts(nxgep, rcrp, cs, -1); } /* error events. */ if (cs.value & RX_DMA_CTL_STAT_ERROR) { (void) nxge_rx_err_evnts(nxgep, channel, cs); } /* * Enable the mailbox update interrupt if we want * to use mailbox. We probably don't need to use * mailbox as it only saves us one pio read. * Also write 1 to rcrthres and rcrto to clear * these two edge triggered bits. */ cs.value &= RX_DMA_CTL_STAT_WR1C; cs.bits.hdw.mex = rcrp->poll_flag ? 0 : 1; RXDMA_REG_WRITE64(handle, RX_DMA_CTL_STAT_REG, channel, cs.value); /* * If the polling mode is enabled, disable the interrupt. */ if (rcrp->poll_flag) { NXGE_DEBUG_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_intr: rdc %d ldgp $%p ldvp $%p " "(disabling interrupts)", channel, ldgp, ldvp)); /* * Disarm this logical group if this is a single device * group. */ if (ldgp->nldvs == 1) { if (isLDOMguest(nxgep)) { ldgp->arm = B_FALSE; nxge_hio_ldgimgn(nxgep, ldgp); } else { ldgimgm_t mgm; mgm.value = 0; mgm.bits.ldw.arm = 0; NXGE_REG_WR64(handle, LDGIMGN_REG + LDSV_OFFSET(ldgp->ldg), mgm.value); } } } else { /* * Rearm this logical group if this is a single device * group. */ if (ldgp->nldvs == 1) { if (isLDOMguest(nxgep)) { nxge_hio_ldgimgn(nxgep, ldgp); } else { ldgimgm_t mgm; mgm.value = 0; mgm.bits.ldw.arm = 1; mgm.bits.ldw.timer = ldgp->ldg_timer; NXGE_REG_WR64(handle, LDGIMGN_REG + LDSV_OFFSET(ldgp->ldg), mgm.value); } } NXGE_DEBUG_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_intr: rdc %d ldgp $%p " "exiting ISR (and call mac_rx_ring)", channel, ldgp)); } MUTEX_EXIT(&rcrp->lock); if (mp != NULL) { mac_rx_ring(nxgep->mach, rcrp->rcr_mac_handle, mp, rcrp->rcr_gen_num); } NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rx_intr: DDI_INTR_CLAIMED")); return (DDI_INTR_CLAIMED); } /* * This routine is the main packet receive processing function. * It gets the packet type, error code, and buffer related * information from the receive completion entry. * How many completion entries to process is based on the number of packets * queued by the hardware, a hardware maintained tail pointer * and a configurable receive packet count. * * A chain of message blocks will be created as result of processing * the completion entries. This chain of message blocks will be returned and * a hardware control status register will be updated with the number of * packets were removed from the hardware queue. * * The RCR ring lock is held when entering this function. */ static mblk_t * nxge_rx_pkts(p_nxge_t nxgep, p_rx_rcr_ring_t rcr_p, rx_dma_ctl_stat_t cs, int bytes_to_pickup) { npi_handle_t handle; uint8_t channel; uint32_t comp_rd_index; p_rcr_entry_t rcr_desc_rd_head_p; p_rcr_entry_t rcr_desc_rd_head_pp; p_mblk_t nmp, mp_cont, head_mp, *tail_mp; uint16_t qlen, nrcr_read, npkt_read; uint32_t qlen_hw; boolean_t multi; rcrcfig_b_t rcr_cfg_b; int totallen = 0; #if defined(_BIG_ENDIAN) npi_status_t rs = NPI_SUCCESS; #endif NXGE_DEBUG_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_pkts: " "channel %d", rcr_p->rdc)); if (!(nxgep->drv_state & STATE_HW_INITIALIZED)) { return (NULL); } handle = NXGE_DEV_NPI_HANDLE(nxgep); channel = rcr_p->rdc; NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rx_pkts: START: rcr channel %d " "head_p $%p head_pp $%p index %d ", channel, rcr_p->rcr_desc_rd_head_p, rcr_p->rcr_desc_rd_head_pp, rcr_p->comp_rd_index)); #if !defined(_BIG_ENDIAN) qlen = RXDMA_REG_READ32(handle, RCRSTAT_A_REG, channel) & 0xffff; #else rs = npi_rxdma_rdc_rcr_qlen_get(handle, channel, &qlen); if (rs != NPI_SUCCESS) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rx_pkts: " "channel %d, get qlen failed 0x%08x", channel, rs)); return (NULL); } #endif NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rx_pkts:rcr channel %d " "qlen %d", channel, qlen)); if (!qlen) { NXGE_DEBUG_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_pkts:rcr channel %d " "qlen %d (no pkts)", channel, qlen)); return (NULL); } comp_rd_index = rcr_p->comp_rd_index; rcr_desc_rd_head_p = rcr_p->rcr_desc_rd_head_p; rcr_desc_rd_head_pp = rcr_p->rcr_desc_rd_head_pp; nrcr_read = npkt_read = 0; /* * Number of packets queued * (The jumbo or multi packet will be counted as only one * packets and it may take up more than one completion entry). */ qlen_hw = (qlen < nxge_max_rx_pkts) ? qlen : nxge_max_rx_pkts; head_mp = NULL; tail_mp = &head_mp; nmp = mp_cont = NULL; multi = B_FALSE; while (qlen_hw) { #ifdef NXGE_DEBUG nxge_dump_rcr_entry(nxgep, rcr_desc_rd_head_p); #endif /* * Process one completion ring entry. */ nxge_receive_packet(nxgep, rcr_p, rcr_desc_rd_head_p, &multi, &nmp, &mp_cont); /* * message chaining modes */ if (nmp) { nmp->b_next = NULL; if (!multi && !mp_cont) { /* frame fits a partition */ *tail_mp = nmp; tail_mp = &nmp->b_next; totallen += MBLKL(nmp); nmp = NULL; } else if (multi && !mp_cont) { /* first segment */ *tail_mp = nmp; tail_mp = &nmp->b_cont; totallen += MBLKL(nmp); } else if (multi && mp_cont) { /* mid of multi segs */ *tail_mp = mp_cont; tail_mp = &mp_cont->b_cont; totallen += MBLKL(mp_cont); } else if (!multi && mp_cont) { /* last segment */ *tail_mp = mp_cont; tail_mp = &nmp->b_next; totallen += MBLKL(mp_cont); nmp = NULL; } } NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rx_pkts: loop: rcr channel %d " "before updating: multi %d " "nrcr_read %d " "npk read %d " "head_pp $%p index %d ", channel, multi, nrcr_read, npkt_read, rcr_desc_rd_head_pp, comp_rd_index)); if (!multi) { qlen_hw--; npkt_read++; } /* * Update the next read entry. */ comp_rd_index = NEXT_ENTRY(comp_rd_index, rcr_p->comp_wrap_mask); rcr_desc_rd_head_p = NEXT_ENTRY_PTR(rcr_desc_rd_head_p, rcr_p->rcr_desc_first_p, rcr_p->rcr_desc_last_p); nrcr_read++; NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rx_pkts: (SAM, process one packet) " "nrcr_read %d", nrcr_read)); NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rx_pkts: loop: rcr channel %d " "multi %d " "nrcr_read %d " "npk read %d " "head_pp $%p index %d ", channel, multi, nrcr_read, npkt_read, rcr_desc_rd_head_pp, comp_rd_index)); if ((bytes_to_pickup != -1) && (totallen >= bytes_to_pickup)) { break; } } rcr_p->rcr_desc_rd_head_pp = rcr_desc_rd_head_pp; rcr_p->comp_rd_index = comp_rd_index; rcr_p->rcr_desc_rd_head_p = rcr_desc_rd_head_p; if ((nxgep->intr_timeout != rcr_p->intr_timeout) || (nxgep->intr_threshold != rcr_p->intr_threshold)) { rcr_p->intr_timeout = (nxgep->intr_timeout < NXGE_RDC_RCR_TIMEOUT_MIN) ? NXGE_RDC_RCR_TIMEOUT_MIN : nxgep->intr_timeout; rcr_p->intr_threshold = (nxgep->intr_threshold < NXGE_RDC_RCR_THRESHOLD_MIN) ? NXGE_RDC_RCR_THRESHOLD_MIN : nxgep->intr_threshold; rcr_cfg_b.value = 0x0ULL; rcr_cfg_b.bits.ldw.entout = 1; rcr_cfg_b.bits.ldw.timeout = rcr_p->intr_timeout; rcr_cfg_b.bits.ldw.pthres = rcr_p->intr_threshold; RXDMA_REG_WRITE64(handle, RCRCFIG_B_REG, channel, rcr_cfg_b.value); } cs.bits.ldw.pktread = npkt_read; cs.bits.ldw.ptrread = nrcr_read; RXDMA_REG_WRITE64(handle, RX_DMA_CTL_STAT_REG, channel, cs.value); NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rx_pkts: EXIT: rcr channel %d " "head_pp $%p index %016llx ", channel, rcr_p->rcr_desc_rd_head_pp, rcr_p->comp_rd_index)); /* * Update RCR buffer pointer read and number of packets * read. */ NXGE_DEBUG_MSG((nxgep, NXGE_ERR_CTL, "<== nxge_rx_pkts: return" "channel %d", rcr_p->rdc)); return (head_mp); } void nxge_receive_packet(p_nxge_t nxgep, p_rx_rcr_ring_t rcr_p, p_rcr_entry_t rcr_desc_rd_head_p, boolean_t *multi_p, mblk_t **mp, mblk_t **mp_cont) { p_mblk_t nmp = NULL; uint64_t multi; uint64_t dcf_err; uint8_t channel; boolean_t first_entry = B_TRUE; boolean_t is_tcp_udp = B_FALSE; boolean_t buffer_free = B_FALSE; boolean_t error_send_up = B_FALSE; uint8_t error_type; uint16_t l2_len; uint16_t skip_len; uint8_t pktbufsz_type; uint64_t rcr_entry; uint64_t *pkt_buf_addr_pp; uint64_t *pkt_buf_addr_p; uint32_t buf_offset; uint32_t bsize; uint32_t error_disp_cnt; uint32_t msg_index; p_rx_rbr_ring_t rx_rbr_p; p_rx_msg_t *rx_msg_ring_p; p_rx_msg_t rx_msg_p; uint16_t sw_offset_bytes = 0, hdr_size = 0; nxge_status_t status = NXGE_OK; boolean_t is_valid = B_FALSE; p_nxge_rx_ring_stats_t rdc_stats; uint32_t bytes_read; uint64_t pkt_type; uint64_t frag; boolean_t pkt_too_long_err = B_FALSE; #ifdef NXGE_DEBUG int dump_len; #endif NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_receive_packet")); first_entry = (*mp == NULL) ? B_TRUE : B_FALSE; rcr_entry = *((uint64_t *)rcr_desc_rd_head_p); multi = (rcr_entry & RCR_MULTI_MASK); dcf_err = (rcr_entry & RCR_DCF_ERROR_MASK); pkt_type = (rcr_entry & RCR_PKT_TYPE_MASK); error_type = ((rcr_entry & RCR_ERROR_MASK) >> RCR_ERROR_SHIFT); frag = (rcr_entry & RCR_FRAG_MASK); l2_len = ((rcr_entry & RCR_L2_LEN_MASK) >> RCR_L2_LEN_SHIFT); pktbufsz_type = ((rcr_entry & RCR_PKTBUFSZ_MASK) >> RCR_PKTBUFSZ_SHIFT); #if defined(__i386) pkt_buf_addr_pp = (uint64_t *)(uint32_t)((rcr_entry & RCR_PKT_BUF_ADDR_MASK) << RCR_PKT_BUF_ADDR_SHIFT); #else pkt_buf_addr_pp = (uint64_t *)((rcr_entry & RCR_PKT_BUF_ADDR_MASK) << RCR_PKT_BUF_ADDR_SHIFT); #endif channel = rcr_p->rdc; NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_receive_packet: entryp $%p entry 0x%0llx " "pkt_buf_addr_pp $%p l2_len %d multi 0x%llx " "error_type 0x%x pkt_type 0x%x " "pktbufsz_type %d ", rcr_desc_rd_head_p, rcr_entry, pkt_buf_addr_pp, l2_len, multi, error_type, pkt_type, pktbufsz_type)); NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_receive_packet: entryp $%p entry 0x%0llx " "pkt_buf_addr_pp $%p l2_len %d multi 0x%llx " "error_type 0x%x pkt_type 0x%x ", rcr_desc_rd_head_p, rcr_entry, pkt_buf_addr_pp, l2_len, multi, error_type, pkt_type)); NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> (rbr) nxge_receive_packet: entry 0x%0llx " "full pkt_buf_addr_pp $%p l2_len %d", rcr_entry, pkt_buf_addr_pp, l2_len)); /* get the stats ptr */ rdc_stats = rcr_p->rdc_stats; if (!l2_len) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_receive_packet: failed: l2 length is 0.")); return; } /* * Software workaround for BMAC hardware limitation that allows * maxframe size of 1526, instead of 1522 for non-jumbo and 0x2406 * instead of 0x2400 for jumbo. */ if (l2_len > nxgep->mac.maxframesize) { pkt_too_long_err = B_TRUE; } /* Hardware sends us 4 bytes of CRC as no stripping is done. */ l2_len -= ETHERFCSL; /* shift 6 bits to get the full io address */ #if defined(__i386) pkt_buf_addr_pp = (uint64_t *)((uint32_t)pkt_buf_addr_pp << RCR_PKT_BUF_ADDR_SHIFT_FULL); #else pkt_buf_addr_pp = (uint64_t *)((uint64_t)pkt_buf_addr_pp << RCR_PKT_BUF_ADDR_SHIFT_FULL); #endif NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> (rbr) nxge_receive_packet: entry 0x%0llx " "full pkt_buf_addr_pp $%p l2_len %d", rcr_entry, pkt_buf_addr_pp, l2_len)); rx_rbr_p = rcr_p->rx_rbr_p; rx_msg_ring_p = rx_rbr_p->rx_msg_ring; if (first_entry) { hdr_size = (rcr_p->full_hdr_flag ? RXDMA_HDR_SIZE_FULL : RXDMA_HDR_SIZE_DEFAULT); NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_receive_packet: first entry 0x%016llx " "pkt_buf_addr_pp $%p l2_len %d hdr %d", rcr_entry, pkt_buf_addr_pp, l2_len, hdr_size)); } MUTEX_ENTER(&rx_rbr_p->lock); NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> (rbr 1) nxge_receive_packet: entry 0x%0llx " "full pkt_buf_addr_pp $%p l2_len %d", rcr_entry, pkt_buf_addr_pp, l2_len)); /* * Packet buffer address in the completion entry points * to the starting buffer address (offset 0). * Use the starting buffer address to locate the corresponding * kernel address. */ status = nxge_rxbuf_pp_to_vp(nxgep, rx_rbr_p, pktbufsz_type, pkt_buf_addr_pp, &pkt_buf_addr_p, &buf_offset, &msg_index); NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> (rbr 2) nxge_receive_packet: entry 0x%0llx " "full pkt_buf_addr_pp $%p l2_len %d", rcr_entry, pkt_buf_addr_pp, l2_len)); if (status != NXGE_OK) { MUTEX_EXIT(&rx_rbr_p->lock); NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_receive_packet: found vaddr failed %d", status)); return; } NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> (rbr 3) nxge_receive_packet: entry 0x%0llx " "full pkt_buf_addr_pp $%p l2_len %d", rcr_entry, pkt_buf_addr_pp, l2_len)); NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> (rbr 4 msgindex %d) nxge_receive_packet: entry 0x%0llx " "full pkt_buf_addr_pp $%p l2_len %d", msg_index, rcr_entry, pkt_buf_addr_pp, l2_len)); rx_msg_p = rx_msg_ring_p[msg_index]; NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> (rbr 4 msgindex %d) nxge_receive_packet: entry 0x%0llx " "full pkt_buf_addr_pp $%p l2_len %d", msg_index, rcr_entry, pkt_buf_addr_pp, l2_len)); switch (pktbufsz_type) { case RCR_PKTBUFSZ_0: bsize = rx_rbr_p->pkt_buf_size0_bytes; NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_receive_packet: 0 buf %d", bsize)); break; case RCR_PKTBUFSZ_1: bsize = rx_rbr_p->pkt_buf_size1_bytes; NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_receive_packet: 1 buf %d", bsize)); break; case RCR_PKTBUFSZ_2: bsize = rx_rbr_p->pkt_buf_size2_bytes; NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_receive_packet: 2 buf %d", bsize)); break; case RCR_SINGLE_BLOCK: bsize = rx_msg_p->block_size; NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_receive_packet: single %d", bsize)); break; default: MUTEX_EXIT(&rx_rbr_p->lock); return; } switch (nxge_rdc_buf_offset) { case SW_OFFSET_NO_OFFSET: sw_offset_bytes = 0; break; case SW_OFFSET_64: sw_offset_bytes = 64; break; case SW_OFFSET_128: sw_offset_bytes = 128; break; case SW_OFFSET_192: sw_offset_bytes = 192; break; case SW_OFFSET_256: sw_offset_bytes = 256; break; case SW_OFFSET_320: sw_offset_bytes = 320; break; case SW_OFFSET_384: sw_offset_bytes = 384; break; case SW_OFFSET_448: sw_offset_bytes = 448; break; default: sw_offset_bytes = 0; break; } DMA_COMMON_SYNC_OFFSET(rx_msg_p->buf_dma, (buf_offset + sw_offset_bytes), (hdr_size + l2_len), DDI_DMA_SYNC_FORCPU); NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_receive_packet: after first dump:usage count")); if (rx_msg_p->cur_usage_cnt == 0) { if (rx_rbr_p->rbr_use_bcopy) { atomic_inc_32(&rx_rbr_p->rbr_consumed); if (rx_rbr_p->rbr_consumed < rx_rbr_p->rbr_threshold_hi) { if (rx_rbr_p->rbr_threshold_lo == 0 || ((rx_rbr_p->rbr_consumed >= rx_rbr_p->rbr_threshold_lo) && (rx_rbr_p->rbr_bufsize_type >= pktbufsz_type))) { rx_msg_p->rx_use_bcopy = B_TRUE; } } else { rx_msg_p->rx_use_bcopy = B_TRUE; } } NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_receive_packet: buf %d (new block) ", bsize)); rx_msg_p->pkt_buf_size_code = pktbufsz_type; rx_msg_p->pkt_buf_size = bsize; rx_msg_p->cur_usage_cnt = 1; if (pktbufsz_type == RCR_SINGLE_BLOCK) { NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_receive_packet: buf %d " "(single block) ", bsize)); /* * Buffer can be reused once the free function * is called. */ rx_msg_p->max_usage_cnt = 1; buffer_free = B_TRUE; } else { rx_msg_p->max_usage_cnt = rx_msg_p->block_size/bsize; if (rx_msg_p->max_usage_cnt == 1) { buffer_free = B_TRUE; } } } else { rx_msg_p->cur_usage_cnt++; if (rx_msg_p->cur_usage_cnt == rx_msg_p->max_usage_cnt) { buffer_free = B_TRUE; } } NXGE_DEBUG_MSG((nxgep, RX_CTL, "msgbuf index = %d l2len %d bytes usage %d max_usage %d ", msg_index, l2_len, rx_msg_p->cur_usage_cnt, rx_msg_p->max_usage_cnt)); if ((error_type) || (dcf_err) || (pkt_too_long_err)) { rdc_stats->ierrors++; if (dcf_err) { rdc_stats->dcf_err++; #ifdef NXGE_DEBUG if (!rdc_stats->dcf_err) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "nxge_receive_packet: channel %d dcf_err rcr" " 0x%llx", channel, rcr_entry)); } #endif NXGE_FM_REPORT_ERROR(nxgep, nxgep->mac.portnum, NULL, NXGE_FM_EREPORT_RDMC_DCF_ERR); } else if (pkt_too_long_err) { rdc_stats->pkt_too_long_err++; NXGE_DEBUG_MSG((nxgep, RX_CTL, " nxge_receive_packet:" " channel %d packet length [%d] > " "maxframesize [%d]", channel, l2_len + ETHERFCSL, nxgep->mac.maxframesize)); } else { /* Update error stats */ error_disp_cnt = NXGE_ERROR_SHOW_MAX; rdc_stats->errlog.compl_err_type = error_type; switch (error_type) { /* * Do not send FMA ereport for RCR_L2_ERROR and * RCR_L4_CSUM_ERROR because most likely they indicate * back pressure rather than HW failures. */ case RCR_L2_ERROR: rdc_stats->l2_err++; if (rdc_stats->l2_err < error_disp_cnt) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, " nxge_receive_packet:" " channel %d RCR L2_ERROR", channel)); } break; case RCR_L4_CSUM_ERROR: error_send_up = B_TRUE; rdc_stats->l4_cksum_err++; if (rdc_stats->l4_cksum_err < error_disp_cnt) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, " nxge_receive_packet:" " channel %d" " RCR L4_CSUM_ERROR", channel)); } break; /* * Do not send FMA ereport for RCR_FFLP_SOFT_ERROR and * RCR_ZCP_SOFT_ERROR because they reflect the same * FFLP and ZCP errors that have been reported by * nxge_fflp.c and nxge_zcp.c. */ case RCR_FFLP_SOFT_ERROR: error_send_up = B_TRUE; rdc_stats->fflp_soft_err++; if (rdc_stats->fflp_soft_err < error_disp_cnt) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, " nxge_receive_packet:" " channel %d" " RCR FFLP_SOFT_ERROR", channel)); } break; case RCR_ZCP_SOFT_ERROR: error_send_up = B_TRUE; rdc_stats->fflp_soft_err++; if (rdc_stats->zcp_soft_err < error_disp_cnt) NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, " nxge_receive_packet: Channel %d" " RCR ZCP_SOFT_ERROR", channel)); break; default: rdc_stats->rcr_unknown_err++; if (rdc_stats->rcr_unknown_err < error_disp_cnt) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, " nxge_receive_packet: Channel %d" " RCR entry 0x%llx error 0x%x", rcr_entry, channel, error_type)); } break; } } /* * Update and repost buffer block if max usage * count is reached. */ if (error_send_up == B_FALSE) { atomic_inc_32(&rx_msg_p->ref_cnt); if (buffer_free == B_TRUE) { rx_msg_p->free = B_TRUE; } MUTEX_EXIT(&rx_rbr_p->lock); nxge_freeb(rx_msg_p); return; } } NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_receive_packet: DMA sync second ")); bytes_read = rcr_p->rcvd_pkt_bytes; skip_len = sw_offset_bytes + hdr_size; if (!rx_msg_p->rx_use_bcopy) { /* * For loaned up buffers, the driver reference count * will be incremented first and then the free state. */ if ((nmp = nxge_dupb(rx_msg_p, buf_offset, bsize)) != NULL) { if (first_entry) { nmp->b_rptr = &nmp->b_rptr[skip_len]; if (l2_len < bsize - skip_len) { nmp->b_wptr = &nmp->b_rptr[l2_len]; } else { nmp->b_wptr = &nmp->b_rptr[bsize - skip_len]; } } else { if (l2_len - bytes_read < bsize) { nmp->b_wptr = &nmp->b_rptr[l2_len - bytes_read]; } else { nmp->b_wptr = &nmp->b_rptr[bsize]; } } } } else { if (first_entry) { nmp = nxge_dupb_bcopy(rx_msg_p, buf_offset + skip_len, l2_len < bsize - skip_len ? l2_len : bsize - skip_len); } else { nmp = nxge_dupb_bcopy(rx_msg_p, buf_offset, l2_len - bytes_read < bsize ? l2_len - bytes_read : bsize); } } if (nmp != NULL) { if (first_entry) { /* * Jumbo packets may be received with more than one * buffer, increment ipackets for the first entry only. */ rdc_stats->ipackets++; /* Update ibytes for kstat. */ rdc_stats->ibytes += skip_len + l2_len < bsize ? l2_len : bsize; /* * Update the number of bytes read so far for the * current frame. */ bytes_read = nmp->b_wptr - nmp->b_rptr; } else { rdc_stats->ibytes += l2_len - bytes_read < bsize ? l2_len - bytes_read : bsize; bytes_read += nmp->b_wptr - nmp->b_rptr; } NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_receive_packet after dupb: " "rbr consumed %d " "pktbufsz_type %d " "nmp $%p rptr $%p wptr $%p " "buf_offset %d bzise %d l2_len %d skip_len %d", rx_rbr_p->rbr_consumed, pktbufsz_type, nmp, nmp->b_rptr, nmp->b_wptr, buf_offset, bsize, l2_len, skip_len)); } else { cmn_err(CE_WARN, "!nxge_receive_packet: " "update stats (error)"); atomic_inc_32(&rx_msg_p->ref_cnt); if (buffer_free == B_TRUE) { rx_msg_p->free = B_TRUE; } MUTEX_EXIT(&rx_rbr_p->lock); nxge_freeb(rx_msg_p); return; } if (buffer_free == B_TRUE) { rx_msg_p->free = B_TRUE; } is_valid = (nmp != NULL); rcr_p->rcvd_pkt_bytes = bytes_read; MUTEX_EXIT(&rx_rbr_p->lock); if (rx_msg_p->free && rx_msg_p->rx_use_bcopy) { atomic_inc_32(&rx_msg_p->ref_cnt); nxge_freeb(rx_msg_p); } if (is_valid) { nmp->b_cont = NULL; if (first_entry) { *mp = nmp; *mp_cont = NULL; } else { *mp_cont = nmp; } } /* * ERROR, FRAG and PKT_TYPE are only reported in the first entry. * If a packet is not fragmented and no error bit is set, then * L4 checksum is OK. */ if (is_valid && !multi) { /* * If the checksum flag nxge_chksum_offload * is 1, TCP and UDP packets can be sent * up with good checksum. If the checksum flag * is set to 0, checksum reporting will apply to * TCP packets only (workaround for a hardware bug). * If the checksum flag nxge_cksum_offload is * greater than 1, both TCP and UDP packets * will not be reported its hardware checksum results. */ if (nxge_cksum_offload == 1) { is_tcp_udp = ((pkt_type == RCR_PKT_IS_TCP || pkt_type == RCR_PKT_IS_UDP) ? B_TRUE: B_FALSE); } else if (!nxge_cksum_offload) { /* TCP checksum only. */ is_tcp_udp = ((pkt_type == RCR_PKT_IS_TCP) ? B_TRUE: B_FALSE); } NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_receive_packet: " "is_valid 0x%x multi 0x%llx pkt %d frag %d error %d", is_valid, multi, is_tcp_udp, frag, error_type)); if (is_tcp_udp && !frag && !error_type) { (void) hcksum_assoc(nmp, NULL, NULL, 0, 0, 0, 0, HCK_FULLCKSUM_OK | HCK_FULLCKSUM, 0); NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_receive_packet: Full tcp/udp cksum " "is_valid 0x%x multi 0x%llx pkt %d frag %d " "error %d", is_valid, multi, is_tcp_udp, frag, error_type)); } } NXGE_DEBUG_MSG((nxgep, RX2_CTL, "==> nxge_receive_packet: *mp 0x%016llx", *mp)); *multi_p = (multi == RCR_MULTI_MASK); NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_receive_packet: " "multi %d nmp 0x%016llx *mp 0x%016llx *mp_cont 0x%016llx", *multi_p, nmp, *mp, *mp_cont)); } /* * Enable polling for a ring. Interrupt for the ring is disabled when * the nxge interrupt comes (see nxge_rx_intr). */ int nxge_enable_poll(void *arg) { p_nxge_ring_handle_t ring_handle = (p_nxge_ring_handle_t)arg; p_rx_rcr_ring_t ringp; p_nxge_t nxgep; p_nxge_ldg_t ldgp; uint32_t channel; if (ring_handle == NULL) { ASSERT(ring_handle != NULL); return (0); } nxgep = ring_handle->nxgep; channel = nxgep->pt_config.hw_config.start_rdc + ring_handle->index; ringp = nxgep->rx_rcr_rings->rcr_rings[channel]; NXGE_DEBUG_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_enable_poll: rdc %d ", ringp->rdc)); ldgp = ringp->ldgp; if (ldgp == NULL) { NXGE_DEBUG_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_enable_poll: rdc %d NULL ldgp: no change", ringp->rdc)); return (0); } MUTEX_ENTER(&ringp->lock); /* enable polling */ if (ringp->poll_flag == 0) { ringp->poll_flag = 1; NXGE_DEBUG_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_enable_poll: rdc %d set poll flag to 1", ringp->rdc)); } MUTEX_EXIT(&ringp->lock); return (0); } /* * Disable polling for a ring and enable its interrupt. */ int nxge_disable_poll(void *arg) { p_nxge_ring_handle_t ring_handle = (p_nxge_ring_handle_t)arg; p_rx_rcr_ring_t ringp; p_nxge_t nxgep; uint32_t channel; if (ring_handle == NULL) { ASSERT(ring_handle != NULL); return (0); } nxgep = ring_handle->nxgep; channel = nxgep->pt_config.hw_config.start_rdc + ring_handle->index; ringp = nxgep->rx_rcr_rings->rcr_rings[channel]; NXGE_DEBUG_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_disable_poll: rdc %d poll_flag %d", ringp->rdc)); MUTEX_ENTER(&ringp->lock); /* disable polling: enable interrupt */ if (ringp->poll_flag) { npi_handle_t handle; rx_dma_ctl_stat_t cs; uint8_t channel; p_nxge_ldg_t ldgp; /* * Get the control and status for this channel. */ handle = NXGE_DEV_NPI_HANDLE(nxgep); channel = ringp->rdc; RXDMA_REG_READ64(handle, RX_DMA_CTL_STAT_REG, channel, &cs.value); /* * Enable mailbox update * Since packets were not read and the hardware uses * bits pktread and ptrread to update the queue * length, we need to set both bits to 0. */ cs.bits.ldw.pktread = 0; cs.bits.ldw.ptrread = 0; cs.bits.hdw.mex = 1; RXDMA_REG_WRITE64(handle, RX_DMA_CTL_STAT_REG, channel, cs.value); /* * Rearm this logical group if this is a single device * group. */ ldgp = ringp->ldgp; if (ldgp == NULL) { ringp->poll_flag = 0; MUTEX_EXIT(&ringp->lock); NXGE_DEBUG_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_disable_poll: no ldgp rdc %d " "(still set poll to 0", ringp->rdc)); return (0); } NXGE_DEBUG_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_disable_poll: rdc %d ldgp $%p (enable intr)", ringp->rdc, ldgp)); if (ldgp->nldvs == 1) { if (isLDOMguest(nxgep)) { ldgp->arm = B_TRUE; nxge_hio_ldgimgn(nxgep, ldgp); } else { ldgimgm_t mgm; mgm.value = 0; mgm.bits.ldw.arm = 1; mgm.bits.ldw.timer = ldgp->ldg_timer; NXGE_REG_WR64(handle, LDGIMGN_REG + LDSV_OFFSET(ldgp->ldg), mgm.value); } } ringp->poll_flag = 0; } MUTEX_EXIT(&ringp->lock); return (0); } /* * Poll 'bytes_to_pickup' bytes of message from the rx ring. */ mblk_t * nxge_rx_poll(void *arg, int bytes_to_pickup) { p_nxge_ring_handle_t ring_handle = (p_nxge_ring_handle_t)arg; p_rx_rcr_ring_t rcr_p; p_nxge_t nxgep; npi_handle_t handle; rx_dma_ctl_stat_t cs; mblk_t *mblk; p_nxge_ldv_t ldvp; uint32_t channel; nxgep = ring_handle->nxgep; /* * Get the control and status for this channel. */ handle = NXGE_DEV_NPI_HANDLE(nxgep); channel = nxgep->pt_config.hw_config.start_rdc + ring_handle->index; rcr_p = nxgep->rx_rcr_rings->rcr_rings[channel]; MUTEX_ENTER(&rcr_p->lock); ASSERT(rcr_p->poll_flag == 1); RXDMA_REG_READ64(handle, RX_DMA_CTL_STAT_REG, rcr_p->rdc, &cs.value); NXGE_DEBUG_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_poll: calling nxge_rx_pkts: rdc %d poll_flag %d", rcr_p->rdc, rcr_p->poll_flag)); mblk = nxge_rx_pkts(nxgep, rcr_p, cs, bytes_to_pickup); ldvp = rcr_p->ldvp; /* error events. */ if (ldvp && (cs.value & RX_DMA_CTL_STAT_ERROR)) { (void) nxge_rx_err_evnts(nxgep, ldvp->vdma_index, cs); } MUTEX_EXIT(&rcr_p->lock); NXGE_DEBUG_MSG((nxgep, NXGE_ERR_CTL, "<== nxge_rx_poll: rdc %d mblk $%p", rcr_p->rdc, mblk)); return (mblk); } /*ARGSUSED*/ static nxge_status_t nxge_rx_err_evnts(p_nxge_t nxgep, int channel, rx_dma_ctl_stat_t cs) { p_nxge_rx_ring_stats_t rdc_stats; npi_handle_t handle; npi_status_t rs; boolean_t rxchan_fatal = B_FALSE; boolean_t rxport_fatal = B_FALSE; uint8_t portn; nxge_status_t status = NXGE_OK; uint32_t error_disp_cnt = NXGE_ERROR_SHOW_MAX; NXGE_DEBUG_MSG((nxgep, INT_CTL, "==> nxge_rx_err_evnts")); handle = NXGE_DEV_NPI_HANDLE(nxgep); portn = nxgep->mac.portnum; rdc_stats = &nxgep->statsp->rdc_stats[channel]; if (cs.bits.hdw.rbr_tmout) { rdc_stats->rx_rbr_tmout++; NXGE_FM_REPORT_ERROR(nxgep, portn, channel, NXGE_FM_EREPORT_RDMC_RBR_TMOUT); rxchan_fatal = B_TRUE; NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_err_evnts: rx_rbr_timeout")); } if (cs.bits.hdw.rsp_cnt_err) { rdc_stats->rsp_cnt_err++; NXGE_FM_REPORT_ERROR(nxgep, portn, channel, NXGE_FM_EREPORT_RDMC_RSP_CNT_ERR); rxchan_fatal = B_TRUE; NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_err_evnts(channel %d): " "rsp_cnt_err", channel)); } if (cs.bits.hdw.byte_en_bus) { rdc_stats->byte_en_bus++; NXGE_FM_REPORT_ERROR(nxgep, portn, channel, NXGE_FM_EREPORT_RDMC_BYTE_EN_BUS); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_err_evnts(channel %d): " "fatal error: byte_en_bus", channel)); rxchan_fatal = B_TRUE; } if (cs.bits.hdw.rsp_dat_err) { rdc_stats->rsp_dat_err++; NXGE_FM_REPORT_ERROR(nxgep, portn, channel, NXGE_FM_EREPORT_RDMC_RSP_DAT_ERR); rxchan_fatal = B_TRUE; NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_err_evnts(channel %d): " "fatal error: rsp_dat_err", channel)); } if (cs.bits.hdw.rcr_ack_err) { rdc_stats->rcr_ack_err++; NXGE_FM_REPORT_ERROR(nxgep, portn, channel, NXGE_FM_EREPORT_RDMC_RCR_ACK_ERR); rxchan_fatal = B_TRUE; NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_err_evnts(channel %d): " "fatal error: rcr_ack_err", channel)); } if (cs.bits.hdw.dc_fifo_err) { rdc_stats->dc_fifo_err++; NXGE_FM_REPORT_ERROR(nxgep, portn, channel, NXGE_FM_EREPORT_RDMC_DC_FIFO_ERR); /* This is not a fatal error! */ NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_err_evnts(channel %d): " "dc_fifo_err", channel)); rxport_fatal = B_TRUE; } if ((cs.bits.hdw.rcr_sha_par) || (cs.bits.hdw.rbr_pre_par)) { if ((rs = npi_rxdma_ring_perr_stat_get(handle, &rdc_stats->errlog.pre_par, &rdc_stats->errlog.sha_par)) != NPI_SUCCESS) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_err_evnts(channel %d): " "rcr_sha_par: get perr", channel)); return (NXGE_ERROR | rs); } if (cs.bits.hdw.rcr_sha_par) { rdc_stats->rcr_sha_par++; NXGE_FM_REPORT_ERROR(nxgep, portn, channel, NXGE_FM_EREPORT_RDMC_RCR_SHA_PAR); rxchan_fatal = B_TRUE; NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_err_evnts(channel %d): " "fatal error: rcr_sha_par", channel)); } if (cs.bits.hdw.rbr_pre_par) { rdc_stats->rbr_pre_par++; NXGE_FM_REPORT_ERROR(nxgep, portn, channel, NXGE_FM_EREPORT_RDMC_RBR_PRE_PAR); rxchan_fatal = B_TRUE; NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_err_evnts(channel %d): " "fatal error: rbr_pre_par", channel)); } } /* * The Following 4 status bits are for information, the system * is running fine. There is no need to send FMA ereports or * log messages. */ if (cs.bits.hdw.port_drop_pkt) { rdc_stats->port_drop_pkt++; } if (cs.bits.hdw.wred_drop) { rdc_stats->wred_drop++; } if (cs.bits.hdw.rbr_pre_empty) { rdc_stats->rbr_pre_empty++; } if (cs.bits.hdw.rcr_shadow_full) { rdc_stats->rcr_shadow_full++; } if (cs.bits.hdw.config_err) { rdc_stats->config_err++; NXGE_FM_REPORT_ERROR(nxgep, portn, channel, NXGE_FM_EREPORT_RDMC_CONFIG_ERR); rxchan_fatal = B_TRUE; NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_err_evnts(channel %d): " "config error", channel)); } if (cs.bits.hdw.rcrincon) { rdc_stats->rcrincon++; NXGE_FM_REPORT_ERROR(nxgep, portn, channel, NXGE_FM_EREPORT_RDMC_RCRINCON); rxchan_fatal = B_TRUE; NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_err_evnts(channel %d): " "fatal error: rcrincon error", channel)); } if (cs.bits.hdw.rcrfull) { rdc_stats->rcrfull++; NXGE_FM_REPORT_ERROR(nxgep, portn, channel, NXGE_FM_EREPORT_RDMC_RCRFULL); rxchan_fatal = B_TRUE; if (rdc_stats->rcrfull < error_disp_cnt) NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_err_evnts(channel %d): " "fatal error: rcrfull error", channel)); } if (cs.bits.hdw.rbr_empty) { /* * This bit is for information, there is no need * send FMA ereport or log a message. */ rdc_stats->rbr_empty++; } if (cs.bits.hdw.rbrfull) { rdc_stats->rbrfull++; NXGE_FM_REPORT_ERROR(nxgep, portn, channel, NXGE_FM_EREPORT_RDMC_RBRFULL); rxchan_fatal = B_TRUE; NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_err_evnts(channel %d): " "fatal error: rbr_full error", channel)); } if (cs.bits.hdw.rbrlogpage) { rdc_stats->rbrlogpage++; NXGE_FM_REPORT_ERROR(nxgep, portn, channel, NXGE_FM_EREPORT_RDMC_RBRLOGPAGE); rxchan_fatal = B_TRUE; NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_err_evnts(channel %d): " "fatal error: rbr logical page error", channel)); } if (cs.bits.hdw.cfiglogpage) { rdc_stats->cfiglogpage++; NXGE_FM_REPORT_ERROR(nxgep, portn, channel, NXGE_FM_EREPORT_RDMC_CFIGLOGPAGE); rxchan_fatal = B_TRUE; NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rx_err_evnts(channel %d): " "fatal error: cfig logical page error", channel)); } if (rxport_fatal) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, " nxge_rx_err_evnts: fatal error on Port #%d\n", portn)); if (isLDOMguest(nxgep)) { status = NXGE_ERROR; } else { status = nxge_ipp_fatal_err_recover(nxgep); if (status == NXGE_OK) { FM_SERVICE_RESTORED(nxgep); } } } if (rxchan_fatal) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, " nxge_rx_err_evnts: fatal error on Channel #%d\n", channel)); if (isLDOMguest(nxgep)) { status = NXGE_ERROR; } else { status = nxge_rxdma_fatal_err_recover(nxgep, channel); if (status == NXGE_OK) { FM_SERVICE_RESTORED(nxgep); } } } NXGE_DEBUG_MSG((nxgep, RX2_CTL, "<== nxge_rx_err_evnts")); return (status); } /* * nxge_rdc_hvio_setup * * This code appears to setup some Hypervisor variables. * * Arguments: * nxgep * channel * * Notes: * What does NIU_LP_WORKAROUND mean? * * NPI/NXGE function calls: * na * * Context: * Any domain */ #if defined(sun4v) && defined(NIU_LP_WORKAROUND) static void nxge_rdc_hvio_setup( nxge_t *nxgep, int channel) { nxge_dma_common_t *dma_common; nxge_dma_common_t *dma_control; rx_rbr_ring_t *ring; ring = nxgep->rx_rbr_rings->rbr_rings[channel]; dma_common = nxgep->rx_buf_pool_p->dma_buf_pool_p[channel]; ring->hv_set = B_FALSE; ring->hv_rx_buf_base_ioaddr_pp = (uint64_t) dma_common->orig_ioaddr_pp; ring->hv_rx_buf_ioaddr_size = (uint64_t) dma_common->orig_alength; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_map_rxdma_channel: " "channel %d data buf base io $%lx ($%p) size 0x%lx (%ld 0x%lx)", channel, ring->hv_rx_buf_base_ioaddr_pp, dma_common->ioaddr_pp, ring->hv_rx_buf_ioaddr_size, dma_common->orig_alength, dma_common->orig_alength)); dma_control = nxgep->rx_cntl_pool_p->dma_buf_pool_p[channel]; ring->hv_rx_cntl_base_ioaddr_pp = (uint64_t)dma_control->orig_ioaddr_pp; ring->hv_rx_cntl_ioaddr_size = (uint64_t)dma_control->orig_alength; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_map_rxdma_channel: " "channel %d cntl base io $%p ($%p) size 0x%llx (%d 0x%x)", channel, ring->hv_rx_cntl_base_ioaddr_pp, dma_control->ioaddr_pp, ring->hv_rx_cntl_ioaddr_size, dma_control->orig_alength, dma_control->orig_alength)); } #endif /* * nxge_map_rxdma * * Map an RDC into our kernel space. * * Arguments: * nxgep * channel The channel to map. * * Notes: * 1. Allocate & initialise a memory pool, if necessary. * 2. Allocate however many receive buffers are required. * 3. Setup buffers, descriptors, and mailbox. * * NPI/NXGE function calls: * nxge_alloc_rx_mem_pool() * nxge_alloc_rbb() * nxge_map_rxdma_channel() * * Registers accessed: * * Context: * Any domain */ static nxge_status_t nxge_map_rxdma(p_nxge_t nxgep, int channel) { nxge_dma_common_t **data; nxge_dma_common_t **control; rx_rbr_ring_t **rbr_ring; rx_rcr_ring_t **rcr_ring; rx_mbox_t **mailbox; uint32_t chunks; nxge_status_t status; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_map_rxdma")); if (!nxgep->rx_buf_pool_p) { if (nxge_alloc_rx_mem_pool(nxgep) != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "<== nxge_map_rxdma: buf not allocated")); return (NXGE_ERROR); } } if (nxge_alloc_rxb(nxgep, channel) != NXGE_OK) return (NXGE_ERROR); /* * Map descriptors from the buffer polls for each dma channel. */ /* * Set up and prepare buffer blocks, descriptors * and mailbox. */ data = &nxgep->rx_buf_pool_p->dma_buf_pool_p[channel]; rbr_ring = &nxgep->rx_rbr_rings->rbr_rings[channel]; chunks = nxgep->rx_buf_pool_p->num_chunks[channel]; control = &nxgep->rx_cntl_pool_p->dma_buf_pool_p[channel]; rcr_ring = &nxgep->rx_rcr_rings->rcr_rings[channel]; mailbox = &nxgep->rx_mbox_areas_p->rxmbox_areas[channel]; status = nxge_map_rxdma_channel(nxgep, channel, data, rbr_ring, chunks, control, rcr_ring, mailbox); if (status != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_map_rxdma: nxge_map_rxdma_channel(%d) " "returned 0x%x", channel, status)); return (status); } nxgep->rx_rbr_rings->rbr_rings[channel]->index = (uint16_t)channel; nxgep->rx_rcr_rings->rcr_rings[channel]->index = (uint16_t)channel; nxgep->rx_rcr_rings->rcr_rings[channel]->rdc_stats = &nxgep->statsp->rdc_stats[channel]; #if defined(sun4v) && defined(NIU_LP_WORKAROUND) if (!isLDOMguest(nxgep)) nxge_rdc_hvio_setup(nxgep, channel); #endif NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_map_rxdma: (status 0x%x channel %d)", status, channel)); return (status); } static void nxge_unmap_rxdma(p_nxge_t nxgep, int channel) { rx_rbr_ring_t *rbr_ring; rx_rcr_ring_t *rcr_ring; rx_mbox_t *mailbox; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_unmap_rxdma(%d)", channel)); if (!nxgep->rx_rbr_rings || !nxgep->rx_rcr_rings || !nxgep->rx_mbox_areas_p) return; rbr_ring = nxgep->rx_rbr_rings->rbr_rings[channel]; rcr_ring = nxgep->rx_rcr_rings->rcr_rings[channel]; mailbox = nxgep->rx_mbox_areas_p->rxmbox_areas[channel]; if (!rbr_ring || !rcr_ring || !mailbox) return; (void) nxge_unmap_rxdma_channel( nxgep, channel, rbr_ring, rcr_ring, mailbox); nxge_free_rxb(nxgep, channel); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_unmap_rxdma")); } nxge_status_t nxge_map_rxdma_channel(p_nxge_t nxgep, uint16_t channel, p_nxge_dma_common_t *dma_buf_p, p_rx_rbr_ring_t *rbr_p, uint32_t num_chunks, p_nxge_dma_common_t *dma_cntl_p, p_rx_rcr_ring_t *rcr_p, p_rx_mbox_t *rx_mbox_p) { int status = NXGE_OK; /* * Set up and prepare buffer blocks, descriptors * and mailbox. */ NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_map_rxdma_channel (channel %d)", channel)); /* * Receive buffer blocks */ status = nxge_map_rxdma_channel_buf_ring(nxgep, channel, dma_buf_p, rbr_p, num_chunks); if (status != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_map_rxdma_channel (channel %d): " "map buffer failed 0x%x", channel, status)); goto nxge_map_rxdma_channel_exit; } /* * Receive block ring, completion ring and mailbox. */ status = nxge_map_rxdma_channel_cfg_ring(nxgep, channel, dma_cntl_p, rbr_p, rcr_p, rx_mbox_p); if (status != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_map_rxdma_channel (channel %d): " "map config failed 0x%x", channel, status)); goto nxge_map_rxdma_channel_fail2; } goto nxge_map_rxdma_channel_exit; nxge_map_rxdma_channel_fail3: /* Free rbr, rcr */ NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_map_rxdma_channel: free rbr/rcr " "(status 0x%x channel %d)", status, channel)); nxge_unmap_rxdma_channel_cfg_ring(nxgep, *rcr_p, *rx_mbox_p); nxge_map_rxdma_channel_fail2: /* Free buffer blocks */ NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_map_rxdma_channel: free rx buffers" "(nxgep 0x%x status 0x%x channel %d)", nxgep, status, channel)); nxge_unmap_rxdma_channel_buf_ring(nxgep, *rbr_p); status = NXGE_ERROR; nxge_map_rxdma_channel_exit: NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_map_rxdma_channel: " "(nxgep 0x%x status 0x%x channel %d)", nxgep, status, channel)); return (status); } /*ARGSUSED*/ static void nxge_unmap_rxdma_channel(p_nxge_t nxgep, uint16_t channel, p_rx_rbr_ring_t rbr_p, p_rx_rcr_ring_t rcr_p, p_rx_mbox_t rx_mbox_p) { NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_unmap_rxdma_channel (channel %d)", channel)); /* * unmap receive block ring, completion ring and mailbox. */ (void) nxge_unmap_rxdma_channel_cfg_ring(nxgep, rcr_p, rx_mbox_p); /* unmap buffer blocks */ (void) nxge_unmap_rxdma_channel_buf_ring(nxgep, rbr_p); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_unmap_rxdma_channel")); } /*ARGSUSED*/ static nxge_status_t nxge_map_rxdma_channel_cfg_ring(p_nxge_t nxgep, uint16_t dma_channel, p_nxge_dma_common_t *dma_cntl_p, p_rx_rbr_ring_t *rbr_p, p_rx_rcr_ring_t *rcr_p, p_rx_mbox_t *rx_mbox_p) { p_rx_rbr_ring_t rbrp; p_rx_rcr_ring_t rcrp; p_rx_mbox_t mboxp; p_nxge_dma_common_t cntl_dmap; p_nxge_dma_common_t dmap; p_rx_msg_t *rx_msg_ring; p_rx_msg_t rx_msg_p; p_rbr_cfig_a_t rcfga_p; p_rbr_cfig_b_t rcfgb_p; p_rcrcfig_a_t cfga_p; p_rcrcfig_b_t cfgb_p; p_rxdma_cfig1_t cfig1_p; p_rxdma_cfig2_t cfig2_p; p_rbr_kick_t kick_p; uint32_t dmaaddrp; uint32_t *rbr_vaddrp; uint32_t bkaddr; nxge_status_t status = NXGE_OK; int i; uint32_t nxge_port_rcr_size; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_map_rxdma_channel_cfg_ring")); cntl_dmap = *dma_cntl_p; /* Map in the receive block ring */ rbrp = *rbr_p; dmap = (p_nxge_dma_common_t)&rbrp->rbr_desc; nxge_setup_dma_common(dmap, cntl_dmap, rbrp->rbb_max, 4); /* * Zero out buffer block ring descriptors. */ bzero((caddr_t)dmap->kaddrp, dmap->alength); rcfga_p = &(rbrp->rbr_cfga); rcfgb_p = &(rbrp->rbr_cfgb); kick_p = &(rbrp->rbr_kick); rcfga_p->value = 0; rcfgb_p->value = 0; kick_p->value = 0; rbrp->rbr_addr = dmap->dma_cookie.dmac_laddress; rcfga_p->value = (rbrp->rbr_addr & (RBR_CFIG_A_STDADDR_MASK | RBR_CFIG_A_STDADDR_BASE_MASK)); rcfga_p->value |= ((uint64_t)rbrp->rbb_max << RBR_CFIG_A_LEN_SHIFT); rcfgb_p->bits.ldw.bufsz0 = rbrp->pkt_buf_size0; rcfgb_p->bits.ldw.vld0 = 1; rcfgb_p->bits.ldw.bufsz1 = rbrp->pkt_buf_size1; rcfgb_p->bits.ldw.vld1 = 1; rcfgb_p->bits.ldw.bufsz2 = rbrp->pkt_buf_size2; rcfgb_p->bits.ldw.vld2 = 1; rcfgb_p->bits.ldw.bksize = nxgep->rx_bksize_code; /* * For each buffer block, enter receive block address to the ring. */ rbr_vaddrp = (uint32_t *)dmap->kaddrp; rbrp->rbr_desc_vp = (uint32_t *)dmap->kaddrp; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_map_rxdma_channel_cfg_ring: channel %d " "rbr_vaddrp $%p", dma_channel, rbr_vaddrp)); rx_msg_ring = rbrp->rx_msg_ring; for (i = 0; i < rbrp->tnblocks; i++) { rx_msg_p = rx_msg_ring[i]; rx_msg_p->nxgep = nxgep; rx_msg_p->rx_rbr_p = rbrp; bkaddr = (uint32_t) ((rx_msg_p->buf_dma.dma_cookie.dmac_laddress >> RBR_BKADDR_SHIFT)); rx_msg_p->free = B_FALSE; rx_msg_p->max_usage_cnt = 0xbaddcafe; *rbr_vaddrp++ = bkaddr; } kick_p->bits.ldw.bkadd = rbrp->rbb_max; rbrp->rbr_wr_index = (rbrp->rbb_max - 1); rbrp->rbr_rd_index = 0; rbrp->rbr_consumed = 0; rbrp->rbr_use_bcopy = B_TRUE; rbrp->rbr_bufsize_type = RCR_PKTBUFSZ_0; /* * Do bcopy on packets greater than bcopy size once * the lo threshold is reached. * This lo threshold should be less than the hi threshold. * * Do bcopy on every packet once the hi threshold is reached. */ if (nxge_rx_threshold_lo >= nxge_rx_threshold_hi) { /* default it to use hi */ nxge_rx_threshold_lo = nxge_rx_threshold_hi; } if (nxge_rx_buf_size_type > NXGE_RBR_TYPE2) { nxge_rx_buf_size_type = NXGE_RBR_TYPE2; } rbrp->rbr_bufsize_type = nxge_rx_buf_size_type; switch (nxge_rx_threshold_hi) { default: case NXGE_RX_COPY_NONE: /* Do not do bcopy at all */ rbrp->rbr_use_bcopy = B_FALSE; rbrp->rbr_threshold_hi = rbrp->rbb_max; break; case NXGE_RX_COPY_1: case NXGE_RX_COPY_2: case NXGE_RX_COPY_3: case NXGE_RX_COPY_4: case NXGE_RX_COPY_5: case NXGE_RX_COPY_6: case NXGE_RX_COPY_7: rbrp->rbr_threshold_hi = rbrp->rbb_max * (nxge_rx_threshold_hi)/NXGE_RX_BCOPY_SCALE; break; case NXGE_RX_COPY_ALL: rbrp->rbr_threshold_hi = 0; break; } switch (nxge_rx_threshold_lo) { default: case NXGE_RX_COPY_NONE: /* Do not do bcopy at all */ if (rbrp->rbr_use_bcopy) { rbrp->rbr_use_bcopy = B_FALSE; } rbrp->rbr_threshold_lo = rbrp->rbb_max; break; case NXGE_RX_COPY_1: case NXGE_RX_COPY_2: case NXGE_RX_COPY_3: case NXGE_RX_COPY_4: case NXGE_RX_COPY_5: case NXGE_RX_COPY_6: case NXGE_RX_COPY_7: rbrp->rbr_threshold_lo = rbrp->rbb_max * (nxge_rx_threshold_lo)/NXGE_RX_BCOPY_SCALE; break; case NXGE_RX_COPY_ALL: rbrp->rbr_threshold_lo = 0; break; } NXGE_DEBUG_MSG((nxgep, RX_CTL, "nxge_map_rxdma_channel_cfg_ring: channel %d " "rbb_max %d " "rbrp->rbr_bufsize_type %d " "rbb_threshold_hi %d " "rbb_threshold_lo %d", dma_channel, rbrp->rbb_max, rbrp->rbr_bufsize_type, rbrp->rbr_threshold_hi, rbrp->rbr_threshold_lo)); rbrp->page_valid.value = 0; rbrp->page_mask_1.value = rbrp->page_mask_2.value = 0; rbrp->page_value_1.value = rbrp->page_value_2.value = 0; rbrp->page_reloc_1.value = rbrp->page_reloc_2.value = 0; rbrp->page_hdl.value = 0; rbrp->page_valid.bits.ldw.page0 = 1; rbrp->page_valid.bits.ldw.page1 = 1; /* Map in the receive completion ring */ rcrp = (p_rx_rcr_ring_t) KMEM_ZALLOC(sizeof (rx_rcr_ring_t), KM_SLEEP); rcrp->rdc = dma_channel; nxge_port_rcr_size = nxgep->nxge_port_rcr_size; rcrp->comp_size = nxge_port_rcr_size; rcrp->comp_wrap_mask = nxge_port_rcr_size - 1; rcrp->max_receive_pkts = nxge_max_rx_pkts; dmap = (p_nxge_dma_common_t)&rcrp->rcr_desc; nxge_setup_dma_common(dmap, cntl_dmap, rcrp->comp_size, sizeof (rcr_entry_t)); rcrp->comp_rd_index = 0; rcrp->comp_wt_index = 0; rcrp->rcr_desc_rd_head_p = rcrp->rcr_desc_first_p = (p_rcr_entry_t)DMA_COMMON_VPTR(rcrp->rcr_desc); #if defined(__i386) rcrp->rcr_desc_rd_head_pp = rcrp->rcr_desc_first_pp = (p_rcr_entry_t)(uint32_t)DMA_COMMON_IOADDR(rcrp->rcr_desc); #else rcrp->rcr_desc_rd_head_pp = rcrp->rcr_desc_first_pp = (p_rcr_entry_t)DMA_COMMON_IOADDR(rcrp->rcr_desc); #endif rcrp->rcr_desc_last_p = rcrp->rcr_desc_rd_head_p + (nxge_port_rcr_size - 1); rcrp->rcr_desc_last_pp = rcrp->rcr_desc_rd_head_pp + (nxge_port_rcr_size - 1); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_map_rxdma_channel_cfg_ring: " "channel %d " "rbr_vaddrp $%p " "rcr_desc_rd_head_p $%p " "rcr_desc_rd_head_pp $%p " "rcr_desc_rd_last_p $%p " "rcr_desc_rd_last_pp $%p ", dma_channel, rbr_vaddrp, rcrp->rcr_desc_rd_head_p, rcrp->rcr_desc_rd_head_pp, rcrp->rcr_desc_last_p, rcrp->rcr_desc_last_pp)); /* * Zero out buffer block ring descriptors. */ bzero((caddr_t)dmap->kaddrp, dmap->alength); rcrp->intr_timeout = (nxgep->intr_timeout < NXGE_RDC_RCR_TIMEOUT_MIN) ? NXGE_RDC_RCR_TIMEOUT_MIN : nxgep->intr_timeout; rcrp->intr_threshold = (nxgep->intr_threshold < NXGE_RDC_RCR_THRESHOLD_MIN) ? NXGE_RDC_RCR_THRESHOLD_MIN : nxgep->intr_threshold; rcrp->full_hdr_flag = B_FALSE; rcrp->sw_priv_hdr_len = nxge_rdc_buf_offset; cfga_p = &(rcrp->rcr_cfga); cfgb_p = &(rcrp->rcr_cfgb); cfga_p->value = 0; cfgb_p->value = 0; rcrp->rcr_addr = dmap->dma_cookie.dmac_laddress; cfga_p->value = (rcrp->rcr_addr & (RCRCFIG_A_STADDR_MASK | RCRCFIG_A_STADDR_BASE_MASK)); rcfga_p->value |= ((uint64_t)rcrp->comp_size << RCRCFIG_A_LEN_SHIF); /* * Timeout should be set based on the system clock divider. * A timeout value of 1 assumes that the * granularity (1000) is 3 microseconds running at 300MHz. */ cfgb_p->bits.ldw.pthres = rcrp->intr_threshold; cfgb_p->bits.ldw.timeout = rcrp->intr_timeout; cfgb_p->bits.ldw.entout = 1; /* Map in the mailbox */ mboxp = (p_rx_mbox_t) KMEM_ZALLOC(sizeof (rx_mbox_t), KM_SLEEP); dmap = (p_nxge_dma_common_t)&mboxp->rx_mbox; nxge_setup_dma_common(dmap, cntl_dmap, 1, sizeof (rxdma_mailbox_t)); cfig1_p = (p_rxdma_cfig1_t)&mboxp->rx_cfg1; cfig2_p = (p_rxdma_cfig2_t)&mboxp->rx_cfg2; cfig1_p->value = cfig2_p->value = 0; mboxp->mbox_addr = dmap->dma_cookie.dmac_laddress; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_map_rxdma_channel_cfg_ring: " "channel %d cfg1 0x%016llx cfig2 0x%016llx cookie 0x%016llx", dma_channel, cfig1_p->value, cfig2_p->value, mboxp->mbox_addr)); dmaaddrp = (uint32_t)(dmap->dma_cookie.dmac_laddress >> 32 & 0xfff); cfig1_p->bits.ldw.mbaddr_h = dmaaddrp; dmaaddrp = (uint32_t)(dmap->dma_cookie.dmac_laddress & 0xffffffff); dmaaddrp = (uint32_t)(dmap->dma_cookie.dmac_laddress & RXDMA_CFIG2_MBADDR_L_MASK); cfig2_p->bits.ldw.mbaddr = (dmaaddrp >> RXDMA_CFIG2_MBADDR_L_SHIFT); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_map_rxdma_channel_cfg_ring: " "channel %d damaddrp $%p " "cfg1 0x%016llx cfig2 0x%016llx", dma_channel, dmaaddrp, cfig1_p->value, cfig2_p->value)); cfig2_p->bits.ldw.full_hdr = rcrp->full_hdr_flag; if (nxgep->niu_hw_type == NIU_HW_TYPE_RF) { switch (rcrp->sw_priv_hdr_len) { case SW_OFFSET_NO_OFFSET: case SW_OFFSET_64: case SW_OFFSET_128: case SW_OFFSET_192: cfig2_p->bits.ldw.offset = rcrp->sw_priv_hdr_len; cfig2_p->bits.ldw.offset256 = 0; break; case SW_OFFSET_256: case SW_OFFSET_320: case SW_OFFSET_384: case SW_OFFSET_448: cfig2_p->bits.ldw.offset = rcrp->sw_priv_hdr_len & 0x3; cfig2_p->bits.ldw.offset256 = 1; break; default: cfig2_p->bits.ldw.offset = SW_OFFSET_NO_OFFSET; cfig2_p->bits.ldw.offset256 = 0; } } else { cfig2_p->bits.ldw.offset = rcrp->sw_priv_hdr_len; } rbrp->rx_rcr_p = rcrp; rcrp->rx_rbr_p = rbrp; *rcr_p = rcrp; *rx_mbox_p = mboxp; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_map_rxdma_channel_cfg_ring status 0x%08x", status)); return (status); } /*ARGSUSED*/ static void nxge_unmap_rxdma_channel_cfg_ring(p_nxge_t nxgep, p_rx_rcr_ring_t rcr_p, p_rx_mbox_t rx_mbox_p) { NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_unmap_rxdma_channel_cfg_ring: channel %d", rcr_p->rdc)); KMEM_FREE(rcr_p, sizeof (rx_rcr_ring_t)); KMEM_FREE(rx_mbox_p, sizeof (rx_mbox_t)); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_unmap_rxdma_channel_cfg_ring")); } static nxge_status_t nxge_map_rxdma_channel_buf_ring(p_nxge_t nxgep, uint16_t channel, p_nxge_dma_common_t *dma_buf_p, p_rx_rbr_ring_t *rbr_p, uint32_t num_chunks) { p_rx_rbr_ring_t rbrp; p_nxge_dma_common_t dma_bufp, tmp_bufp; p_rx_msg_t *rx_msg_ring; p_rx_msg_t rx_msg_p; p_mblk_t mblk_p; rxring_info_t *ring_info; nxge_status_t status = NXGE_OK; int i, j, index; uint32_t size, bsize, nblocks, nmsgs; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_map_rxdma_channel_buf_ring: channel %d", channel)); dma_bufp = tmp_bufp = *dma_buf_p; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, " nxge_map_rxdma_channel_buf_ring: channel %d to map %d " "chunks bufp 0x%016llx", channel, num_chunks, dma_bufp)); nmsgs = 0; for (i = 0; i < num_chunks; i++, tmp_bufp++) { NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_map_rxdma_channel_buf_ring: channel %d " "bufp 0x%016llx nblocks %d nmsgs %d", channel, tmp_bufp, tmp_bufp->nblocks, nmsgs)); nmsgs += tmp_bufp->nblocks; } if (!nmsgs) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "<== nxge_map_rxdma_channel_buf_ring: channel %d " "no msg blocks", channel)); status = NXGE_ERROR; goto nxge_map_rxdma_channel_buf_ring_exit; } rbrp = (p_rx_rbr_ring_t)KMEM_ZALLOC(sizeof (*rbrp), KM_SLEEP); size = nmsgs * sizeof (p_rx_msg_t); rx_msg_ring = KMEM_ZALLOC(size, KM_SLEEP); ring_info = (rxring_info_t *)KMEM_ZALLOC(sizeof (rxring_info_t), KM_SLEEP); MUTEX_INIT(&rbrp->lock, NULL, MUTEX_DRIVER, (void *)nxgep->interrupt_cookie); MUTEX_INIT(&rbrp->post_lock, NULL, MUTEX_DRIVER, (void *)nxgep->interrupt_cookie); rbrp->rdc = channel; rbrp->num_blocks = num_chunks; rbrp->tnblocks = nmsgs; rbrp->rbb_max = nmsgs; rbrp->rbr_max_size = nmsgs; rbrp->rbr_wrap_mask = (rbrp->rbb_max - 1); /* * Buffer sizes suggested by NIU architect. * 256, 512 and 2K. */ rbrp->pkt_buf_size0 = RBR_BUFSZ0_256B; rbrp->pkt_buf_size0_bytes = RBR_BUFSZ0_256_BYTES; rbrp->npi_pkt_buf_size0 = SIZE_256B; rbrp->pkt_buf_size1 = RBR_BUFSZ1_1K; rbrp->pkt_buf_size1_bytes = RBR_BUFSZ1_1K_BYTES; rbrp->npi_pkt_buf_size1 = SIZE_1KB; rbrp->block_size = nxgep->rx_default_block_size; if (!nxgep->mac.is_jumbo) { rbrp->pkt_buf_size2 = RBR_BUFSZ2_2K; rbrp->pkt_buf_size2_bytes = RBR_BUFSZ2_2K_BYTES; rbrp->npi_pkt_buf_size2 = SIZE_2KB; } else { if (rbrp->block_size >= 0x2000) { rbrp->pkt_buf_size2 = RBR_BUFSZ2_8K; rbrp->pkt_buf_size2_bytes = RBR_BUFSZ2_8K_BYTES; rbrp->npi_pkt_buf_size2 = SIZE_8KB; } else { rbrp->pkt_buf_size2 = RBR_BUFSZ2_4K; rbrp->pkt_buf_size2_bytes = RBR_BUFSZ2_4K_BYTES; rbrp->npi_pkt_buf_size2 = SIZE_4KB; } } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_map_rxdma_channel_buf_ring: channel %d " "actual rbr max %d rbb_max %d nmsgs %d " "rbrp->block_size %d default_block_size %d " "(config nxge_rbr_size %d nxge_rbr_spare_size %d)", channel, rbrp->rbr_max_size, rbrp->rbb_max, nmsgs, rbrp->block_size, nxgep->rx_default_block_size, nxge_rbr_size, nxge_rbr_spare_size)); /* Map in buffers from the buffer pool. */ index = 0; for (i = 0; i < rbrp->num_blocks; i++, dma_bufp++) { bsize = dma_bufp->block_size; nblocks = dma_bufp->nblocks; #if defined(__i386) ring_info->buffer[i].dvma_addr = (uint32_t)dma_bufp->ioaddr_pp; #else ring_info->buffer[i].dvma_addr = (uint64_t)dma_bufp->ioaddr_pp; #endif ring_info->buffer[i].buf_index = i; ring_info->buffer[i].buf_size = dma_bufp->alength; ring_info->buffer[i].start_index = index; #if defined(__i386) ring_info->buffer[i].kaddr = (uint32_t)dma_bufp->kaddrp; #else ring_info->buffer[i].kaddr = (uint64_t)dma_bufp->kaddrp; #endif NXGE_DEBUG_MSG((nxgep, MEM2_CTL, " nxge_map_rxdma_channel_buf_ring: map channel %d " "chunk %d" " nblocks %d chunk_size %x block_size 0x%x " "dma_bufp $%p", channel, i, dma_bufp->nblocks, ring_info->buffer[i].buf_size, bsize, dma_bufp)); for (j = 0; j < nblocks; j++) { if ((rx_msg_p = nxge_allocb(bsize, BPRI_LO, dma_bufp)) == NULL) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "allocb failed (index %d i %d j %d)", index, i, j)); goto nxge_map_rxdma_channel_buf_ring_fail1; } rx_msg_ring[index] = rx_msg_p; rx_msg_p->block_index = index; rx_msg_p->shifted_addr = (uint32_t) ((rx_msg_p->buf_dma.dma_cookie.dmac_laddress >> RBR_BKADDR_SHIFT)); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "index %d j %d rx_msg_p $%p mblk %p", index, j, rx_msg_p, rx_msg_p->rx_mblk_p)); mblk_p = rx_msg_p->rx_mblk_p; mblk_p->b_wptr = mblk_p->b_rptr + bsize; rbrp->rbr_ref_cnt++; index++; rx_msg_p->buf_dma.dma_channel = channel; } rbrp->rbr_alloc_type = DDI_MEM_ALLOC; if (dma_bufp->contig_alloc_type) { rbrp->rbr_alloc_type = CONTIG_MEM_ALLOC; } if (dma_bufp->kmem_alloc_type) { rbrp->rbr_alloc_type = KMEM_ALLOC; } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, " nxge_map_rxdma_channel_buf_ring: map channel %d " "chunk %d" " nblocks %d chunk_size %x block_size 0x%x " "dma_bufp $%p", channel, i, dma_bufp->nblocks, ring_info->buffer[i].buf_size, bsize, dma_bufp)); } if (i < rbrp->num_blocks) { goto nxge_map_rxdma_channel_buf_ring_fail1; } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "nxge_map_rxdma_channel_buf_ring: done buf init " "channel %d msg block entries %d", channel, index)); ring_info->block_size_mask = bsize - 1; rbrp->rx_msg_ring = rx_msg_ring; rbrp->dma_bufp = dma_buf_p; rbrp->ring_info = ring_info; status = nxge_rxbuf_index_info_init(nxgep, rbrp); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, " nxge_map_rxdma_channel_buf_ring: " "channel %d done buf info init", channel)); /* * Finally, permit nxge_freeb() to call nxge_post_page(). */ rbrp->rbr_state = RBR_POSTING; *rbr_p = rbrp; goto nxge_map_rxdma_channel_buf_ring_exit; nxge_map_rxdma_channel_buf_ring_fail1: NXGE_DEBUG_MSG((nxgep, MEM2_CTL, " nxge_map_rxdma_channel_buf_ring: failed channel (0x%x)", channel, status)); index--; for (; index >= 0; index--) { rx_msg_p = rx_msg_ring[index]; if (rx_msg_p != NULL) { freeb(rx_msg_p->rx_mblk_p); rx_msg_ring[index] = NULL; } } nxge_map_rxdma_channel_buf_ring_fail: MUTEX_DESTROY(&rbrp->post_lock); MUTEX_DESTROY(&rbrp->lock); KMEM_FREE(ring_info, sizeof (rxring_info_t)); KMEM_FREE(rx_msg_ring, size); KMEM_FREE(rbrp, sizeof (rx_rbr_ring_t)); status = NXGE_ERROR; nxge_map_rxdma_channel_buf_ring_exit: NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_map_rxdma_channel_buf_ring status 0x%08x", status)); return (status); } /*ARGSUSED*/ static void nxge_unmap_rxdma_channel_buf_ring(p_nxge_t nxgep, p_rx_rbr_ring_t rbr_p) { p_rx_msg_t *rx_msg_ring; p_rx_msg_t rx_msg_p; rxring_info_t *ring_info; int i; uint32_t size; #ifdef NXGE_DEBUG int num_chunks; #endif NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_unmap_rxdma_channel_buf_ring")); if (rbr_p == NULL) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_unmap_rxdma_channel_buf_ring: NULL rbrp")); return; } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_unmap_rxdma_channel_buf_ring: channel %d", rbr_p->rdc)); rx_msg_ring = rbr_p->rx_msg_ring; ring_info = rbr_p->ring_info; if (rx_msg_ring == NULL || ring_info == NULL) { NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_unmap_rxdma_channel_buf_ring: " "rx_msg_ring $%p ring_info $%p", rx_msg_p, ring_info)); return; } #ifdef NXGE_DEBUG num_chunks = rbr_p->num_blocks; #endif size = rbr_p->tnblocks * sizeof (p_rx_msg_t); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, " nxge_unmap_rxdma_channel_buf_ring: channel %d chunks %d " "tnblocks %d (max %d) size ptrs %d ", rbr_p->rdc, num_chunks, rbr_p->tnblocks, rbr_p->rbr_max_size, size)); for (i = 0; i < rbr_p->tnblocks; i++) { rx_msg_p = rx_msg_ring[i]; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, " nxge_unmap_rxdma_channel_buf_ring: " "rx_msg_p $%p", rx_msg_p)); if (rx_msg_p != NULL) { freeb(rx_msg_p->rx_mblk_p); rx_msg_ring[i] = NULL; } } /* * We no longer may use the mutex . By setting * to anything but POSTING, we prevent * nxge_post_page() from accessing a dead mutex. */ rbr_p->rbr_state = RBR_UNMAPPING; MUTEX_DESTROY(&rbr_p->post_lock); MUTEX_DESTROY(&rbr_p->lock); if (rbr_p->rbr_ref_cnt == 0) { /* * This is the normal state of affairs. * Need to free the following buffers: * - data buffers * - rx_msg ring * - ring_info * - rbr ring */ NXGE_DEBUG_MSG((nxgep, RX_CTL, "unmap_rxdma_buf_ring: No outstanding - freeing ")); nxge_rxdma_databuf_free(rbr_p); KMEM_FREE(ring_info, sizeof (rxring_info_t)); KMEM_FREE(rx_msg_ring, size); KMEM_FREE(rbr_p, sizeof (*rbr_p)); } else { /* * Some of our buffers are still being used. * Therefore, tell nxge_freeb() this ring is * unmapped, so it may free for us. */ rbr_p->rbr_state = RBR_UNMAPPED; NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "unmap_rxdma_buf_ring: %d %s outstanding.", rbr_p->rbr_ref_cnt, rbr_p->rbr_ref_cnt == 1 ? "msg" : "msgs")); } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_unmap_rxdma_channel_buf_ring")); } /* * nxge_rxdma_hw_start_common * * Arguments: * nxgep * * Notes: * * NPI/NXGE function calls: * nxge_init_fzc_rx_common(); * nxge_init_fzc_rxdma_port(); * * Registers accessed: * * Context: * Service domain */ static nxge_status_t nxge_rxdma_hw_start_common(p_nxge_t nxgep) { nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_hw_start_common")); /* * Load the sharable parameters by writing to the * function zero control registers. These FZC registers * should be initialized only once for the entire chip. */ (void) nxge_init_fzc_rx_common(nxgep); /* * Initialize the RXDMA port specific FZC control configurations. * These FZC registers are pertaining to each port. */ (void) nxge_init_fzc_rxdma_port(nxgep); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_hw_start_common")); return (status); } static nxge_status_t nxge_rxdma_hw_start(p_nxge_t nxgep, int channel) { int i, ndmas; p_rx_rbr_rings_t rx_rbr_rings; p_rx_rbr_ring_t *rbr_rings; p_rx_rcr_rings_t rx_rcr_rings; p_rx_rcr_ring_t *rcr_rings; p_rx_mbox_areas_t rx_mbox_areas_p; p_rx_mbox_t *rx_mbox_p; nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_hw_start")); rx_rbr_rings = nxgep->rx_rbr_rings; rx_rcr_rings = nxgep->rx_rcr_rings; if (rx_rbr_rings == NULL || rx_rcr_rings == NULL) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rxdma_hw_start: NULL ring pointers")); return (NXGE_ERROR); } ndmas = rx_rbr_rings->ndmas; if (ndmas == 0) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rxdma_hw_start: no dma channel allocated")); return (NXGE_ERROR); } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_hw_start (ndmas %d)", ndmas)); rbr_rings = rx_rbr_rings->rbr_rings; rcr_rings = rx_rcr_rings->rcr_rings; rx_mbox_areas_p = nxgep->rx_mbox_areas_p; if (rx_mbox_areas_p) { rx_mbox_p = rx_mbox_areas_p->rxmbox_areas; } i = channel; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_hw_start (ndmas %d) channel %d", ndmas, channel)); status = nxge_rxdma_start_channel(nxgep, channel, (p_rx_rbr_ring_t)rbr_rings[i], (p_rx_rcr_ring_t)rcr_rings[i], (p_rx_mbox_t)rx_mbox_p[i]); if (status != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rxdma_hw_start: disable " "(status 0x%x channel %d)", status, channel)); return (status); } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_hw_start: " "rx_rbr_rings 0x%016llx rings 0x%016llx", rx_rbr_rings, rx_rcr_rings)); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_hw_start: (status 0x%x)", status)); return (status); } static void nxge_rxdma_hw_stop(p_nxge_t nxgep, int channel) { p_rx_rbr_rings_t rx_rbr_rings; p_rx_rcr_rings_t rx_rcr_rings; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_hw_stop")); rx_rbr_rings = nxgep->rx_rbr_rings; rx_rcr_rings = nxgep->rx_rcr_rings; if (rx_rbr_rings == NULL || rx_rcr_rings == NULL) { NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rxdma_hw_stop: NULL ring pointers")); return; } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_hw_stop(channel %d)", channel)); (void) nxge_rxdma_stop_channel(nxgep, channel); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_hw_stop: " "rx_rbr_rings 0x%016llx rings 0x%016llx", rx_rbr_rings, rx_rcr_rings)); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_rxdma_hw_stop")); } static nxge_status_t nxge_rxdma_start_channel(p_nxge_t nxgep, uint16_t channel, p_rx_rbr_ring_t rbr_p, p_rx_rcr_ring_t rcr_p, p_rx_mbox_t mbox_p) { npi_handle_t handle; npi_status_t rs = NPI_SUCCESS; rx_dma_ctl_stat_t cs; rx_dma_ent_msk_t ent_mask; nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_start_channel")); handle = NXGE_DEV_NPI_HANDLE(nxgep); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "nxge_rxdma_start_channel: " "npi handle addr $%p acc $%p", nxgep->npi_handle.regp, nxgep->npi_handle.regh)); /* Reset RXDMA channel, but not if you're a guest. */ if (!isLDOMguest(nxgep)) { rs = npi_rxdma_cfg_rdc_reset(handle, channel); if (rs != NPI_SUCCESS) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_init_fzc_rdc: " "npi_rxdma_cfg_rdc_reset(%d) returned 0x%08x", channel, rs)); return (NXGE_ERROR | rs); } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_start_channel: reset done: channel %d", channel)); } #if defined(sun4v) && defined(NIU_LP_WORKAROUND) if (isLDOMguest(nxgep)) (void) nxge_rdc_lp_conf(nxgep, channel); #endif /* * Initialize the RXDMA channel specific FZC control * configurations. These FZC registers are pertaining * to each RX channel (logical pages). */ if (!isLDOMguest(nxgep)) { status = nxge_init_fzc_rxdma_channel(nxgep, channel); if (status != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rxdma_start_channel: " "init fzc rxdma failed (0x%08x channel %d)", status, channel)); return (status); } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_start_channel: fzc done")); } /* Set up the interrupt event masks. */ ent_mask.value = 0; ent_mask.value |= RX_DMA_ENT_MSK_RBREMPTY_MASK; rs = npi_rxdma_event_mask(handle, OP_SET, channel, &ent_mask); if (rs != NPI_SUCCESS) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rxdma_start_channel: " "init rxdma event masks failed " "(0x%08x channel %d)", status, channel)); return (NXGE_ERROR | rs); } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_start_channel: " "event done: channel %d (mask 0x%016llx)", channel, ent_mask.value)); /* Initialize the receive DMA control and status register */ cs.value = 0; cs.bits.hdw.mex = 1; cs.bits.hdw.rcrthres = 1; cs.bits.hdw.rcrto = 1; cs.bits.hdw.rbr_empty = 1; status = nxge_init_rxdma_channel_cntl_stat(nxgep, channel, &cs); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_start_channel: " "channel %d rx_dma_cntl_stat 0x%0016llx", channel, cs.value)); if (status != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rxdma_start_channel: " "init rxdma control register failed (0x%08x channel %d", status, channel)); return (status); } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_start_channel: " "control done - channel %d cs 0x%016llx", channel, cs.value)); /* * Load RXDMA descriptors, buffers, mailbox, * initialise the receive DMA channels and * enable each DMA channel. */ status = nxge_enable_rxdma_channel(nxgep, channel, rbr_p, rcr_p, mbox_p); if (status != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, " nxge_rxdma_start_channel: " " enable rxdma failed (0x%08x channel %d)", status, channel)); return (status); } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_start_channel: enabled channel %d")); if (isLDOMguest(nxgep)) { /* Add interrupt handler for this channel. */ status = nxge_hio_intr_add(nxgep, VP_BOUND_RX, channel); if (status != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, " nxge_rxdma_start_channel: " " nxge_hio_intr_add failed (0x%08x channel %d)", status, channel)); return (status); } } ent_mask.value = 0; ent_mask.value |= (RX_DMA_ENT_MSK_WRED_DROP_MASK | RX_DMA_ENT_MSK_PTDROP_PKT_MASK); rs = npi_rxdma_event_mask(handle, OP_SET, channel, &ent_mask); if (rs != NPI_SUCCESS) { NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_start_channel: " "init rxdma event masks failed (0x%08x channel %d)", status, channel)); return (NXGE_ERROR | rs); } NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "==> nxge_rxdma_start_channel: " "control done - channel %d cs 0x%016llx", channel, cs.value)); NXGE_DEBUG_MSG((nxgep, MEM2_CTL, "<== nxge_rxdma_start_channel")); return (NXGE_OK); } static nxge_status_t nxge_rxdma_stop_channel(p_nxge_t nxgep, uint16_t channel) { npi_handle_t handle; npi_status_t rs = NPI_SUCCESS; rx_dma_ctl_stat_t cs; rx_dma_ent_msk_t ent_mask; nxge_status_t status = NXGE_OK; NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rxdma_stop_channel")); handle = NXGE_DEV_NPI_HANDLE(nxgep); NXGE_DEBUG_MSG((nxgep, RX_CTL, "nxge_rxdma_stop_channel: " "npi handle addr $%p acc $%p", nxgep->npi_handle.regp, nxgep->npi_handle.regh)); if (!isLDOMguest(nxgep)) { /* * Stop RxMAC = A.9.2.6 */ if (nxge_rx_mac_disable(nxgep) != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_rxdma_stop_channel: " "Failed to disable RxMAC")); } /* * Drain IPP Port = A.9.3.6 */ (void) nxge_ipp_drain(nxgep); } /* Reset RXDMA channel */ rs = npi_rxdma_cfg_rdc_reset(handle, channel); if (rs != NPI_SUCCESS) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, " nxge_rxdma_stop_channel: " " reset rxdma failed (0x%08x channel %d)", rs, channel)); return (NXGE_ERROR | rs); } NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rxdma_stop_channel: reset done")); /* Set up the interrupt event masks. */ ent_mask.value = RX_DMA_ENT_MSK_ALL; rs = npi_rxdma_event_mask(handle, OP_SET, channel, &ent_mask); if (rs != NPI_SUCCESS) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "==> nxge_rxdma_stop_channel: " "set rxdma event masks failed (0x%08x channel %d)", rs, channel)); return (NXGE_ERROR | rs); } NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rxdma_stop_channel: event done")); /* * Initialize the receive DMA control and status register */ cs.value = 0; status = nxge_init_rxdma_channel_cntl_stat(nxgep, channel, &cs); NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rxdma_stop_channel: control " " to default (all 0s) 0x%08x", cs.value)); if (status != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, " nxge_rxdma_stop_channel: init rxdma" " control register failed (0x%08x channel %d", status, channel)); return (status); } NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rxdma_stop_channel: control done")); /* * Make sure channel is disabled. */ status = nxge_disable_rxdma_channel(nxgep, channel); if (status != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, " nxge_rxdma_stop_channel: " " init enable rxdma failed (0x%08x channel %d)", status, channel)); return (status); } if (!isLDOMguest(nxgep)) { /* * Enable RxMAC = A.9.2.10 */ if (nxge_rx_mac_enable(nxgep) != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_rxdma_stop_channel: Rx MAC still disabled")); } } NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rxdma_stop_channel: disable done")); NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rxdma_stop_channel")); return (NXGE_OK); } nxge_status_t nxge_rxdma_handle_sys_errors(p_nxge_t nxgep) { npi_handle_t handle; p_nxge_rdc_sys_stats_t statsp; rx_ctl_dat_fifo_stat_t stat; uint32_t zcp_err_status; uint32_t ipp_err_status; nxge_status_t status = NXGE_OK; npi_status_t rs = NPI_SUCCESS; boolean_t my_err = B_FALSE; handle = nxgep->npi_handle; statsp = (p_nxge_rdc_sys_stats_t)&nxgep->statsp->rdc_sys_stats; rs = npi_rxdma_rxctl_fifo_error_intr_get(handle, &stat); if (rs != NPI_SUCCESS) return (NXGE_ERROR | rs); if (stat.bits.ldw.id_mismatch) { statsp->id_mismatch++; NXGE_FM_REPORT_ERROR(nxgep, nxgep->mac.portnum, NULL, NXGE_FM_EREPORT_RDMC_ID_MISMATCH); /* Global fatal error encountered */ } if ((stat.bits.ldw.zcp_eop_err) || (stat.bits.ldw.ipp_eop_err)) { switch (nxgep->mac.portnum) { case 0: if ((stat.bits.ldw.zcp_eop_err & FIFO_EOP_PORT0) || (stat.bits.ldw.ipp_eop_err & FIFO_EOP_PORT0)) { my_err = B_TRUE; zcp_err_status = stat.bits.ldw.zcp_eop_err; ipp_err_status = stat.bits.ldw.ipp_eop_err; } break; case 1: if ((stat.bits.ldw.zcp_eop_err & FIFO_EOP_PORT1) || (stat.bits.ldw.ipp_eop_err & FIFO_EOP_PORT1)) { my_err = B_TRUE; zcp_err_status = stat.bits.ldw.zcp_eop_err; ipp_err_status = stat.bits.ldw.ipp_eop_err; } break; case 2: if ((stat.bits.ldw.zcp_eop_err & FIFO_EOP_PORT2) || (stat.bits.ldw.ipp_eop_err & FIFO_EOP_PORT2)) { my_err = B_TRUE; zcp_err_status = stat.bits.ldw.zcp_eop_err; ipp_err_status = stat.bits.ldw.ipp_eop_err; } break; case 3: if ((stat.bits.ldw.zcp_eop_err & FIFO_EOP_PORT3) || (stat.bits.ldw.ipp_eop_err & FIFO_EOP_PORT3)) { my_err = B_TRUE; zcp_err_status = stat.bits.ldw.zcp_eop_err; ipp_err_status = stat.bits.ldw.ipp_eop_err; } break; default: return (NXGE_ERROR); } } if (my_err) { status = nxge_rxdma_handle_port_errors(nxgep, ipp_err_status, zcp_err_status); if (status != NXGE_OK) return (status); } return (NXGE_OK); } static nxge_status_t nxge_rxdma_handle_port_errors(p_nxge_t nxgep, uint32_t ipp_status, uint32_t zcp_status) { boolean_t rxport_fatal = B_FALSE; p_nxge_rdc_sys_stats_t statsp; nxge_status_t status = NXGE_OK; uint8_t portn; portn = nxgep->mac.portnum; statsp = (p_nxge_rdc_sys_stats_t)&nxgep->statsp->rdc_sys_stats; if (ipp_status & (0x1 << portn)) { statsp->ipp_eop_err++; NXGE_FM_REPORT_ERROR(nxgep, portn, NULL, NXGE_FM_EREPORT_RDMC_IPP_EOP_ERR); rxport_fatal = B_TRUE; } if (zcp_status & (0x1 << portn)) { statsp->zcp_eop_err++; NXGE_FM_REPORT_ERROR(nxgep, portn, NULL, NXGE_FM_EREPORT_RDMC_ZCP_EOP_ERR); rxport_fatal = B_TRUE; } if (rxport_fatal) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, " nxge_rxdma_handle_port_error: " " fatal error on Port #%d\n", portn)); status = nxge_rx_port_fatal_err_recover(nxgep); if (status == NXGE_OK) { FM_SERVICE_RESTORED(nxgep); } } return (status); } static nxge_status_t nxge_rxdma_fatal_err_recover(p_nxge_t nxgep, uint16_t channel) { npi_handle_t handle; npi_status_t rs = NPI_SUCCESS; nxge_status_t status = NXGE_OK; p_rx_rbr_ring_t rbrp; p_rx_rcr_ring_t rcrp; p_rx_mbox_t mboxp; rx_dma_ent_msk_t ent_mask; p_nxge_dma_common_t dmap; uint32_t ref_cnt; p_rx_msg_t rx_msg_p; int i; uint32_t nxge_port_rcr_size; NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rxdma_fatal_err_recover")); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Recovering from RxDMAChannel#%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 = NXGE_DEV_NPI_HANDLE(nxgep); NXGE_DEBUG_MSG((nxgep, RX_CTL, "Rx DMA stop...")); rbrp = (p_rx_rbr_ring_t)nxgep->rx_rbr_rings->rbr_rings[channel]; rcrp = (p_rx_rcr_ring_t)nxgep->rx_rcr_rings->rcr_rings[channel]; MUTEX_ENTER(&rbrp->lock); MUTEX_ENTER(&rbrp->post_lock); NXGE_DEBUG_MSG((nxgep, RX_CTL, "Disable RxDMA channel...")); rs = npi_rxdma_cfg_rdc_disable(handle, channel); if (rs != NPI_SUCCESS) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_disable_rxdma_channel:failed")); goto fail; } NXGE_DEBUG_MSG((nxgep, RX_CTL, "Disable RxDMA interrupt...")); /* Disable interrupt */ ent_mask.value = RX_DMA_ENT_MSK_ALL; rs = npi_rxdma_event_mask(handle, OP_SET, channel, &ent_mask); if (rs != NPI_SUCCESS) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_rxdma_stop_channel: " "set rxdma event masks failed (channel %d)", channel)); } NXGE_DEBUG_MSG((nxgep, RX_CTL, "RxDMA channel reset...")); /* Reset RXDMA channel */ rs = npi_rxdma_cfg_rdc_reset(handle, channel); if (rs != NPI_SUCCESS) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_rxdma_fatal_err_recover: " " reset rxdma failed (channel %d)", channel)); goto fail; } nxge_port_rcr_size = nxgep->nxge_port_rcr_size; mboxp = (p_rx_mbox_t)nxgep->rx_mbox_areas_p->rxmbox_areas[channel]; rbrp->rbr_wr_index = (rbrp->rbb_max - 1); rbrp->rbr_rd_index = 0; rcrp->comp_rd_index = 0; rcrp->comp_wt_index = 0; rcrp->rcr_desc_rd_head_p = rcrp->rcr_desc_first_p = (p_rcr_entry_t)DMA_COMMON_VPTR(rcrp->rcr_desc); #if defined(__i386) rcrp->rcr_desc_rd_head_pp = rcrp->rcr_desc_first_pp = (p_rcr_entry_t)(uint32_t)DMA_COMMON_IOADDR(rcrp->rcr_desc); #else rcrp->rcr_desc_rd_head_pp = rcrp->rcr_desc_first_pp = (p_rcr_entry_t)DMA_COMMON_IOADDR(rcrp->rcr_desc); #endif rcrp->rcr_desc_last_p = rcrp->rcr_desc_rd_head_p + (nxge_port_rcr_size - 1); rcrp->rcr_desc_last_pp = rcrp->rcr_desc_rd_head_pp + (nxge_port_rcr_size - 1); dmap = (p_nxge_dma_common_t)&rcrp->rcr_desc; bzero((caddr_t)dmap->kaddrp, dmap->alength); cmn_err(CE_NOTE, "!rbr entries = %d\n", rbrp->rbr_max_size); for (i = 0; i < rbrp->rbr_max_size; i++) { rx_msg_p = rbrp->rx_msg_ring[i]; ref_cnt = rx_msg_p->ref_cnt; if (ref_cnt != 1) { if (rx_msg_p->cur_usage_cnt != rx_msg_p->max_usage_cnt) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "buf[%d]: cur_usage_cnt = %d " "max_usage_cnt = %d\n", i, rx_msg_p->cur_usage_cnt, rx_msg_p->max_usage_cnt)); } else { /* Buffer can be re-posted */ rx_msg_p->free = B_TRUE; rx_msg_p->cur_usage_cnt = 0; rx_msg_p->max_usage_cnt = 0xbaddcafe; rx_msg_p->pkt_buf_size = 0; } } } NXGE_DEBUG_MSG((nxgep, RX_CTL, "RxDMA channel re-start...")); status = nxge_rxdma_start_channel(nxgep, channel, rbrp, rcrp, mboxp); if (status != NXGE_OK) { goto fail; } MUTEX_EXIT(&rbrp->post_lock); MUTEX_EXIT(&rbrp->lock); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Recovery Successful, RxDMAChannel#%d Restored", channel)); NXGE_DEBUG_MSG((nxgep, RX_CTL, "==> nxge_rxdma_fatal_err_recover")); return (NXGE_OK); fail: MUTEX_EXIT(&rbrp->post_lock); MUTEX_EXIT(&rbrp->lock); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Recovery failed")); return (NXGE_ERROR | rs); } nxge_status_t nxge_rx_port_fatal_err_recover(p_nxge_t nxgep) { nxge_grp_set_t *set = &nxgep->rx_set; nxge_status_t status = NXGE_OK; p_rx_rcr_ring_t rcrp; int rdc; NXGE_DEBUG_MSG((nxgep, RX_CTL, "<== nxge_rx_port_fatal_err_recover")); NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Recovering from RxPort error...")); NXGE_DEBUG_MSG((nxgep, RX_CTL, "Disabling RxMAC...\n")); if (nxge_rx_mac_disable(nxgep) != NXGE_OK) goto fail; NXGE_DELAY(1000); NXGE_DEBUG_MSG((nxgep, RX_CTL, "Stopping all RxDMA channels...")); for (rdc = 0; rdc < NXGE_MAX_RDCS; rdc++) { if ((1 << rdc) & set->owned.map) { rcrp = nxgep->rx_rcr_rings->rcr_rings[rdc]; if (rcrp != NULL) { MUTEX_ENTER(&rcrp->lock); if (nxge_rxdma_fatal_err_recover(nxgep, rdc) != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Could not recover " "channel %d", rdc)); } MUTEX_EXIT(&rcrp->lock); } } } NXGE_DEBUG_MSG((nxgep, RX_CTL, "Resetting IPP...")); /* Reset IPP */ if (nxge_ipp_reset(nxgep) != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_rx_port_fatal_err_recover: " "Failed to reset IPP")); goto fail; } NXGE_DEBUG_MSG((nxgep, RX_CTL, "Reset RxMAC...")); /* Reset RxMAC */ if (nxge_rx_mac_reset(nxgep) != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_rx_port_fatal_err_recover: " "Failed to reset RxMAC")); goto fail; } NXGE_DEBUG_MSG((nxgep, RX_CTL, "Re-initialize IPP...")); /* Re-Initialize IPP */ if (nxge_ipp_init(nxgep) != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_rx_port_fatal_err_recover: " "Failed to init IPP")); goto fail; } NXGE_DEBUG_MSG((nxgep, RX_CTL, "Re-initialize RxMAC...")); /* Re-Initialize RxMAC */ if ((status = nxge_rx_mac_init(nxgep)) != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_rx_port_fatal_err_recover: " "Failed to reset RxMAC")); goto fail; } NXGE_DEBUG_MSG((nxgep, RX_CTL, "Re-enable RxMAC...")); /* Re-enable RxMAC */ if ((status = nxge_rx_mac_enable(nxgep)) != NXGE_OK) { NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "nxge_rx_port_fatal_err_recover: " "Failed to enable RxMAC")); goto fail; } NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Recovery Successful, RxPort Restored")); return (NXGE_OK); fail: NXGE_ERROR_MSG((nxgep, NXGE_ERR_CTL, "Recovery failed")); return (status); } void nxge_rxdma_inject_err(p_nxge_t nxgep, uint32_t err_id, uint8_t chan) { rx_dma_ctl_stat_t cs; rx_ctl_dat_fifo_stat_t cdfs; switch (err_id) { case NXGE_FM_EREPORT_RDMC_RCR_ACK_ERR: case NXGE_FM_EREPORT_RDMC_DC_FIFO_ERR: case NXGE_FM_EREPORT_RDMC_RCR_SHA_PAR: case NXGE_FM_EREPORT_RDMC_RBR_PRE_PAR: case NXGE_FM_EREPORT_RDMC_RBR_TMOUT: case NXGE_FM_EREPORT_RDMC_RSP_CNT_ERR: case NXGE_FM_EREPORT_RDMC_BYTE_EN_BUS: case NXGE_FM_EREPORT_RDMC_RSP_DAT_ERR: case NXGE_FM_EREPORT_RDMC_RCRINCON: case NXGE_FM_EREPORT_RDMC_RCRFULL: case NXGE_FM_EREPORT_RDMC_RBRFULL: case NXGE_FM_EREPORT_RDMC_RBRLOGPAGE: case NXGE_FM_EREPORT_RDMC_CFIGLOGPAGE: case NXGE_FM_EREPORT_RDMC_CONFIG_ERR: RXDMA_REG_READ64(nxgep->npi_handle, RX_DMA_CTL_STAT_DBG_REG, chan, &cs.value); if (err_id == NXGE_FM_EREPORT_RDMC_RCR_ACK_ERR) cs.bits.hdw.rcr_ack_err = 1; else if (err_id == NXGE_FM_EREPORT_RDMC_DC_FIFO_ERR) cs.bits.hdw.dc_fifo_err = 1; else if (err_id == NXGE_FM_EREPORT_RDMC_RCR_SHA_PAR) cs.bits.hdw.rcr_sha_par = 1; else if (err_id == NXGE_FM_EREPORT_RDMC_RBR_PRE_PAR) cs.bits.hdw.rbr_pre_par = 1; else if (err_id == NXGE_FM_EREPORT_RDMC_RBR_TMOUT) cs.bits.hdw.rbr_tmout = 1; else if (err_id == NXGE_FM_EREPORT_RDMC_RSP_CNT_ERR) cs.bits.hdw.rsp_cnt_err = 1; else if (err_id == NXGE_FM_EREPORT_RDMC_BYTE_EN_BUS) cs.bits.hdw.byte_en_bus = 1; else if (err_id == NXGE_FM_EREPORT_RDMC_RSP_DAT_ERR) cs.bits.hdw.rsp_dat_err = 1; else if (err_id == NXGE_FM_EREPORT_RDMC_CONFIG_ERR) cs.bits.hdw.config_err = 1; else if (err_id == NXGE_FM_EREPORT_RDMC_RCRINCON) cs.bits.hdw.rcrincon = 1; else if (err_id == NXGE_FM_EREPORT_RDMC_RCRFULL) cs.bits.hdw.rcrfull = 1; else if (err_id == NXGE_FM_EREPORT_RDMC_RBRFULL) cs.bits.hdw.rbrfull = 1; else if (err_id == NXGE_FM_EREPORT_RDMC_RBRLOGPAGE) cs.bits.hdw.rbrlogpage = 1; else if (err_id == NXGE_FM_EREPORT_RDMC_CFIGLOGPAGE) cs.bits.hdw.cfiglogpage = 1; #if defined(__i386) cmn_err(CE_NOTE, "!Write 0x%llx to RX_DMA_CTL_STAT_DBG_REG\n", cs.value); #else cmn_err(CE_NOTE, "!Write 0x%lx to RX_DMA_CTL_STAT_DBG_REG\n", cs.value); #endif RXDMA_REG_WRITE64(nxgep->npi_handle, RX_DMA_CTL_STAT_DBG_REG, chan, cs.value); break; case NXGE_FM_EREPORT_RDMC_ID_MISMATCH: case NXGE_FM_EREPORT_RDMC_ZCP_EOP_ERR: case NXGE_FM_EREPORT_RDMC_IPP_EOP_ERR: cdfs.value = 0; if (err_id == NXGE_FM_EREPORT_RDMC_ID_MISMATCH) cdfs.bits.ldw.id_mismatch = (1 << nxgep->mac.portnum); else if (err_id == NXGE_FM_EREPORT_RDMC_ZCP_EOP_ERR) cdfs.bits.ldw.zcp_eop_err = (1 << nxgep->mac.portnum); else if (err_id == NXGE_FM_EREPORT_RDMC_IPP_EOP_ERR) cdfs.bits.ldw.ipp_eop_err = (1 << nxgep->mac.portnum); #if defined(__i386) cmn_err(CE_NOTE, "!Write 0x%llx to RX_CTL_DAT_FIFO_STAT_DBG_REG\n", cdfs.value); #else cmn_err(CE_NOTE, "!Write 0x%lx to RX_CTL_DAT_FIFO_STAT_DBG_REG\n", cdfs.value); #endif NXGE_REG_WR64(nxgep->npi_handle, RX_CTL_DAT_FIFO_STAT_DBG_REG, cdfs.value); break; case NXGE_FM_EREPORT_RDMC_DCF_ERR: break; case NXGE_FM_EREPORT_RDMC_RCR_ERR: break; } } static void nxge_rxdma_databuf_free(p_rx_rbr_ring_t rbr_p) { rxring_info_t *ring_info; int index; uint32_t chunk_size; uint64_t kaddr; uint_t num_blocks; NXGE_DEBUG_MSG((NULL, DMA_CTL, "==> nxge_rxdma_databuf_free")); if (rbr_p == NULL) { NXGE_ERROR_MSG((NULL, NXGE_ERR_CTL, "==> nxge_rxdma_databuf_free: NULL rbr pointer")); return; } if (rbr_p->rbr_alloc_type == DDI_MEM_ALLOC) { NXGE_DEBUG_MSG((NULL, DMA_CTL, "<== nxge_rxdma_databuf_free: DDI")); return; } ring_info = rbr_p->ring_info; if (ring_info == NULL) { NXGE_ERROR_MSG((NULL, NXGE_ERR_CTL, "==> nxge_rxdma_databuf_free: NULL ring info")); return; } num_blocks = rbr_p->num_blocks; for (index = 0; index < num_blocks; index++) { kaddr = ring_info->buffer[index].kaddr; chunk_size = ring_info->buffer[index].buf_size; NXGE_DEBUG_MSG((NULL, DMA_CTL, "==> nxge_rxdma_databuf_free: free chunk %d " "kaddrp $%p chunk size %d", index, kaddr, chunk_size)); if (kaddr == NULL) continue; nxge_free_buf(rbr_p->rbr_alloc_type, kaddr, chunk_size); ring_info->buffer[index].kaddr = NULL; } NXGE_DEBUG_MSG((NULL, DMA_CTL, "<== nxge_rxdma_databuf_free")); } #if defined(sun4v) && defined(NIU_LP_WORKAROUND) extern void contig_mem_free(void *, size_t); #endif void nxge_free_buf(buf_alloc_type_t alloc_type, uint64_t kaddr, uint32_t buf_size) { NXGE_DEBUG_MSG((NULL, DMA_CTL, "==> nxge_free_buf")); if (kaddr == NULL || !buf_size) { NXGE_ERROR_MSG((NULL, NXGE_ERR_CTL, "==> nxge_free_buf: invalid kaddr $%p size to free %d", kaddr, buf_size)); return; } switch (alloc_type) { case KMEM_ALLOC: NXGE_DEBUG_MSG((NULL, DMA_CTL, "==> nxge_free_buf: freeing kmem $%p size %d", kaddr, buf_size)); #if defined(__i386) KMEM_FREE((void *)(uint32_t)kaddr, buf_size); #else KMEM_FREE((void *)kaddr, buf_size); #endif break; #if defined(sun4v) && defined(NIU_LP_WORKAROUND) case CONTIG_MEM_ALLOC: NXGE_DEBUG_MSG((NULL, DMA_CTL, "==> nxge_free_buf: freeing contig_mem kaddr $%p size %d", kaddr, buf_size)); contig_mem_free((void *)kaddr, buf_size); break; #endif default: NXGE_ERROR_MSG((NULL, NXGE_ERR_CTL, "<== nxge_free_buf: unsupported alloc type %d", alloc_type)); return; } NXGE_DEBUG_MSG((NULL, DMA_CTL, "<== nxge_free_buf")); }