/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #include /* * Ethernet broadcast address definition. */ static ether_addr_st etherbroadcastaddr = {\ 0xff, 0xff, 0xff, 0xff, 0xff, 0xff \ }; static hxge_status_t hxge_pfc_set_mac_address(p_hxge_t, uint32_t, struct ether_addr *); static uint32_t crc32_mchash(p_ether_addr_t addr); static hxge_status_t hxge_pfc_load_hash_table(p_hxge_t hxgep); static uint32_t hxge_get_blade_id(p_hxge_t hxgep); static hxge_status_t hxge_tcam_default_add_entry(p_hxge_t hxgep, tcam_class_t class); static hxge_status_t hxge_tcam_default_config(p_hxge_t hxgep); hxge_status_t hxge_classify_init(p_hxge_t hxgep) { hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_classify_init")); status = hxge_classify_init_sw(hxgep); if (status != HXGE_OK) return (status); status = hxge_classify_init_hw(hxgep); if (status != HXGE_OK) { (void) hxge_classify_exit_sw(hxgep); return (status); } HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_classify_init")); return (HXGE_OK); } hxge_status_t hxge_classify_uninit(p_hxge_t hxgep) { return (hxge_classify_exit_sw(hxgep)); } static hxge_status_t hxge_tcam_dump_entry(p_hxge_t hxgep, uint32_t location) { hxge_tcam_entry_t tcam_rdptr; uint64_t asc_ram = 0; hpi_handle_t handle; hpi_status_t status; handle = hxgep->hpi_reg_handle; /* Retrieve the saved entry */ bcopy((void *)&hxgep->classifier.tcam_entries[location].tce, (void *)&tcam_rdptr, sizeof (hxge_tcam_entry_t)); /* Compare the entry */ status = hpi_pfc_tcam_entry_read(handle, location, &tcam_rdptr); if (status == HPI_FAILURE) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_tcam_dump_entry: tcam read failed at location %d ", location)); return (HXGE_ERROR); } status = hpi_pfc_tcam_asc_ram_entry_read(handle, location, &asc_ram); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "location %x\n" " key: %llx %llx\n mask: %llx %llx\n ASC RAM %llx \n", location, tcam_rdptr.key0, tcam_rdptr.key1, tcam_rdptr.mask0, tcam_rdptr.mask1, asc_ram)); return (HXGE_OK); } void hxge_get_tcam(p_hxge_t hxgep, p_mblk_t mp) { uint32_t tcam_loc; uint32_t *lptr; int location; int start_location = 0; int stop_location = hxgep->classifier.tcam_size; lptr = (uint32_t *)mp->b_rptr; location = *lptr; if ((location >= hxgep->classifier.tcam_size) || (location < -1)) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_tcam_dump: Invalid location %d \n", location)); return; } if (location == -1) { start_location = 0; stop_location = hxgep->classifier.tcam_size; } else { start_location = location; stop_location = location + 1; } for (tcam_loc = start_location; tcam_loc < stop_location; tcam_loc++) (void) hxge_tcam_dump_entry(hxgep, tcam_loc); } /*ARGSUSED*/ static hxge_status_t hxge_add_tcam_entry(p_hxge_t hxgep, flow_resource_t *flow_res) { return (HXGE_OK); } void hxge_put_tcam(p_hxge_t hxgep, p_mblk_t mp) { flow_resource_t *fs; fs = (flow_resource_t *)mp->b_rptr; HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_put_tcam addr fs $%p type %x offset %x", fs, fs->flow_spec.flow_type, fs->channel_cookie)); (void) hxge_add_tcam_entry(hxgep, fs); } static uint32_t hxge_get_blade_id(p_hxge_t hxgep) { phy_debug_training_vec_t blade_id; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_get_blade_id")); HXGE_REG_RD32(hxgep->hpi_reg_handle, PHY_DEBUG_TRAINING_VEC, &blade_id.value); HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_get_blade_id: id = %d", blade_id.bits.bld_num)); return (blade_id.bits.bld_num); } static hxge_status_t hxge_tcam_default_add_entry(p_hxge_t hxgep, tcam_class_t class) { hpi_status_t rs = HPI_SUCCESS; uint32_t location; hxge_tcam_entry_t entry; hxge_tcam_spread_t *key = NULL; hxge_tcam_spread_t *mask = NULL; hpi_handle_t handle; p_hxge_hw_list_t hw_p; if ((hw_p = hxgep->hxge_hw_p) == NULL) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_tcam_default_add_entry: common hardware not set")); return (HXGE_ERROR); } bzero(&entry, sizeof (hxge_tcam_entry_t)); /* * The class id and blade id are common for all classes * Only use the blade id for matching and the rest are wild cards. * This will allow one TCAM entry to match all traffic in order * to spread the traffic using source hash. */ key = &entry.key.spread; mask = &entry.mask.spread; key->blade_id = hxge_get_blade_id(hxgep); mask->class_code = 0x1f; mask->blade_id = 0; mask->wild1 = 0x7ffffff; mask->wild = ~0x0; location = class; handle = hxgep->hpi_reg_handle; MUTEX_ENTER(&hw_p->hxge_tcam_lock); rs = hpi_pfc_tcam_entry_write(handle, location, &entry); if (rs & HPI_PFC_ERROR) { MUTEX_EXIT(&hw_p->hxge_tcam_lock); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_tcam_default_add_entry tcam entry write" " failed for location %d", location)); return (HXGE_ERROR); } /* Add the associative portion */ entry.match_action.value = 0; /* Use source hash to spread traffic */ entry.match_action.bits.channel_d = 0; entry.match_action.bits.channel_c = 1; entry.match_action.bits.channel_b = 2; entry.match_action.bits.channel_a = 3; entry.match_action.bits.source_hash = 1; entry.match_action.bits.discard = 0; rs = hpi_pfc_tcam_asc_ram_entry_write(handle, location, entry.match_action.value); if (rs & HPI_PFC_ERROR) { MUTEX_EXIT(&hw_p->hxge_tcam_lock); HXGE_DEBUG_MSG((hxgep, PFC_CTL, " hxge_tcam_default_add_entry tcam entry write" " failed for ASC RAM location %d", location)); return (HXGE_ERROR); } bcopy((void *) &entry, (void *) &hxgep->classifier.tcam_entries[location].tce, sizeof (hxge_tcam_entry_t)); MUTEX_EXIT(&hw_p->hxge_tcam_lock); return (HXGE_OK); } /* * Configure one TCAM entry for each class and make it match * everything within the class in order to spread the traffic * among the DMA channels based on the source hash. * * This is the default for now. This may change when Crossbow is * available for configuring TCAM. */ static hxge_status_t hxge_tcam_default_config(p_hxge_t hxgep) { uint8_t class; uint32_t class_config; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_tcam_default_config")); /* * Add TCAM and its associative ram entries * A wild card will be used for the class code in order to match * any classes. */ class = 0; status = hxge_tcam_default_add_entry(hxgep, class); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_tcam_default_config " "hxge_tcam_default_add_entry failed class %d ", class)); return (HXGE_ERROR); } /* Enable the classes */ for (class = TCAM_CLASS_TCP_IPV4; class <= TCAM_CLASS_SCTP_IPV6; class++) { /* * By default, it is set to HXGE_CLASS_TCAM_LOOKUP in * hxge_ndd.c. It may be overwritten in hxge.conf. */ class_config = hxgep->class_config.class_cfg[class]; status = hxge_pfc_ip_class_config(hxgep, class, class_config); if (status & HPI_PFC_ERROR) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_tcam_default_config " "hxge_pfc_ip_class_config failed " " class %d config %x ", class, class_config)); return (HXGE_ERROR); } } status = hxge_pfc_config_tcam_enable(hxgep); HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_tcam_default_config")); return (status); } hxge_status_t hxge_pfc_set_default_mac_addr(p_hxge_t hxgep) { hxge_status_t status; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_pfc_set_default_mac_addr")); MUTEX_ENTER(&hxgep->ouraddr_lock); /* * Set new interface local address and re-init device. * This is destructive to any other streams attached * to this device. */ RW_ENTER_WRITER(&hxgep->filter_lock); status = hxge_pfc_set_mac_address(hxgep, HXGE_MAC_DEFAULT_ADDR_SLOT, &hxgep->ouraddr); RW_EXIT(&hxgep->filter_lock); MUTEX_EXIT(&hxgep->ouraddr_lock); HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_pfc_set_default_mac_addr")); return (status); } hxge_status_t hxge_set_mac_addr(p_hxge_t hxgep, struct ether_addr *addrp) { hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_set_mac_addr")); MUTEX_ENTER(&hxgep->ouraddr_lock); /* * Exit if the address is same as ouraddr or multicast or broadcast */ if (((addrp->ether_addr_octet[0] & 01) == 1) || (ether_cmp(addrp, ðerbroadcastaddr) == 0) || (ether_cmp(addrp, &hxgep->ouraddr) == 0)) { goto hxge_set_mac_addr_exit; } hxgep->ouraddr = *addrp; /* * Set new interface local address and re-init device. * This is destructive to any other streams attached * to this device. */ RW_ENTER_WRITER(&hxgep->filter_lock); status = hxge_pfc_set_mac_address(hxgep, HXGE_MAC_DEFAULT_ADDR_SLOT, addrp); RW_EXIT(&hxgep->filter_lock); MUTEX_EXIT(&hxgep->ouraddr_lock); goto hxge_set_mac_addr_end; hxge_set_mac_addr_exit: MUTEX_EXIT(&hxgep->ouraddr_lock); hxge_set_mac_addr_end: HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_set_mac_addr")); return (status); fail: MUTEX_EXIT(&hxgep->ouraddr_lock); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_set_mac_addr: " "Unable to set mac address")); return (status); } /* * Add a multicast address entry into the HW hash table */ hxge_status_t hxge_add_mcast_addr(p_hxge_t hxgep, struct ether_addr *addrp) { uint32_t mchash; p_hash_filter_t hash_filter; uint16_t hash_bit; boolean_t rx_init = B_FALSE; uint_t j; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_add_mcast_addr")); RW_ENTER_WRITER(&hxgep->filter_lock); mchash = crc32_mchash(addrp); if (hxgep->hash_filter == NULL) { HXGE_DEBUG_MSG((NULL, STR_CTL, "Allocating hash filter storage.")); hxgep->hash_filter = KMEM_ZALLOC(sizeof (hash_filter_t), KM_SLEEP); } hash_filter = hxgep->hash_filter; /* * Note that mchash is an 8 bit value and thus 0 <= mchash <= 255. * Consequently, 0 <= j <= 15 and 0 <= mchash % HASH_REG_WIDTH <= 15. */ j = mchash / HASH_REG_WIDTH; hash_bit = (1 << (mchash % HASH_REG_WIDTH)); hash_filter->hash_filter_regs[j] |= hash_bit; hash_filter->hash_bit_ref_cnt[mchash]++; if (hash_filter->hash_bit_ref_cnt[mchash] == 1) { hash_filter->hash_ref_cnt++; rx_init = B_TRUE; } if (rx_init) { (void) hpi_pfc_set_l2_hash(hxgep->hpi_reg_handle, B_FALSE); (void) hxge_pfc_load_hash_table(hxgep); (void) hpi_pfc_set_l2_hash(hxgep->hpi_reg_handle, B_TRUE); } RW_EXIT(&hxgep->filter_lock); HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_add_mcast_addr")); return (HXGE_OK); fail: RW_EXIT(&hxgep->filter_lock); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_add_mcast_addr: " "Unable to add multicast address")); return (status); } /* * Remove a multicast address entry from the HW hash table */ hxge_status_t hxge_del_mcast_addr(p_hxge_t hxgep, struct ether_addr *addrp) { uint32_t mchash; p_hash_filter_t hash_filter; uint16_t hash_bit; boolean_t rx_init = B_FALSE; uint_t j; hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_del_mcast_addr")); RW_ENTER_WRITER(&hxgep->filter_lock); mchash = crc32_mchash(addrp); if (hxgep->hash_filter == NULL) { HXGE_DEBUG_MSG((NULL, STR_CTL, "Hash filter already de_allocated.")); RW_EXIT(&hxgep->filter_lock); HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_del_mcast_addr")); return (HXGE_OK); } hash_filter = hxgep->hash_filter; hash_filter->hash_bit_ref_cnt[mchash]--; if (hash_filter->hash_bit_ref_cnt[mchash] == 0) { j = mchash / HASH_REG_WIDTH; hash_bit = (1 << (mchash % HASH_REG_WIDTH)); hash_filter->hash_filter_regs[j] &= ~hash_bit; hash_filter->hash_ref_cnt--; rx_init = B_TRUE; } if (hash_filter->hash_ref_cnt == 0) { HXGE_DEBUG_MSG((NULL, STR_CTL, "De-allocating hash filter storage.")); KMEM_FREE(hash_filter, sizeof (hash_filter_t)); hxgep->hash_filter = NULL; } if (rx_init) { (void) hpi_pfc_set_l2_hash(hxgep->hpi_reg_handle, B_FALSE); (void) hxge_pfc_load_hash_table(hxgep); /* Enable hash only if there are any hash entries */ if (hxgep->hash_filter != NULL) (void) hpi_pfc_set_l2_hash(hxgep->hpi_reg_handle, B_TRUE); } RW_EXIT(&hxgep->filter_lock); HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_del_mcast_addr")); return (HXGE_OK); fail: RW_EXIT(&hxgep->filter_lock); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_del_mcast_addr: " "Unable to remove multicast address")); return (status); } static hxge_status_t hxge_pfc_set_mac_address(p_hxge_t hxgep, uint32_t slot, struct ether_addr *addrp) { hpi_handle_t handle; uint64_t addr; hpi_status_t hpi_status; uint8_t *address = addrp->ether_addr_octet; uint64_t tmp; int i; if (hxgep->hxge_hw_p == NULL) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_pfc_set_mac_address: common hardware not set")); return (HXGE_ERROR); } /* * Convert a byte array to a 48 bit value. * Need to check endianess if in doubt */ addr = 0; for (i = 0; i < ETHERADDRL; i++) { tmp = address[i]; addr <<= 8; addr |= tmp; } handle = hxgep->hpi_reg_handle; hpi_status = hpi_pfc_set_mac_address(handle, slot, addr); if (hpi_status != HPI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_pfc_set_mac_address: failed to set address")); return (HXGE_ERROR); } return (HXGE_OK); } /*ARGSUSED*/ hxge_status_t hxge_pfc_num_macs_get(p_hxge_t hxgep, uint32_t *nmacs) { *nmacs = PFC_N_MAC_ADDRESSES; return (HXGE_OK); } hxge_status_t hxge_pfc_set_hash(p_hxge_t hxgep, uint32_t seed) { hpi_status_t rs = HPI_SUCCESS; hpi_handle_t handle; p_hxge_class_pt_cfg_t p_class_cfgp; HXGE_DEBUG_MSG((hxgep, PFC_CTL, " ==> hxge_pfc_set_hash")); p_class_cfgp = (p_hxge_class_pt_cfg_t)&hxgep->class_config; p_class_cfgp->init_hash = seed; handle = hxgep->hpi_reg_handle; rs = hpi_pfc_set_hash_seed_value(handle, seed); if (rs & HPI_PFC_ERROR) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_pfc_set_hash %x failed ", seed)); return (HXGE_ERROR | rs); } HXGE_DEBUG_MSG((hxgep, PFC_CTL, " <== hxge_pfc_set_hash")); return (HXGE_OK); } hxge_status_t hxge_pfc_config_tcam_enable(p_hxge_t hxgep) { hpi_handle_t handle; boolean_t enable = B_TRUE; hpi_status_t hpi_status; handle = hxgep->hpi_reg_handle; if (hxgep->hxge_hw_p == NULL) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_pfc_config_tcam_enable: common hardware not set")); return (HXGE_ERROR); } hpi_status = hpi_pfc_set_tcam_enable(handle, enable); if (hpi_status != HPI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hpi_pfc_set_tcam_enable: enable tcam failed")); return (HXGE_ERROR); } return (HXGE_OK); } hxge_status_t hxge_pfc_config_tcam_disable(p_hxge_t hxgep) { hpi_handle_t handle; boolean_t enable = B_FALSE; hpi_status_t hpi_status; handle = hxgep->hpi_reg_handle; if (hxgep->hxge_hw_p == NULL) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_pfc_config_tcam_disable: common hardware not set")); return (HXGE_ERROR); } hpi_status = hpi_pfc_set_tcam_enable(handle, enable); if (hpi_status != HPI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hpi_pfc_set_tcam_enable: disable tcam failed")); return (HXGE_ERROR); } return (HXGE_OK); } static hxge_status_t hxge_cfg_tcam_ip_class_get(p_hxge_t hxgep, tcam_class_t class, uint32_t *class_config) { hpi_status_t rs = HPI_SUCCESS; tcam_key_cfg_t cfg; hpi_handle_t handle; uint32_t ccfg = 0; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_cfg_tcam_ip_class_get")); bzero(&cfg, sizeof (tcam_key_cfg_t)); handle = hxgep->hpi_reg_handle; rs = hpi_pfc_get_l3_class_config(handle, class, &cfg); if (rs & HPI_PFC_ERROR) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_cfg_tcam_ip_class opt %x for class %d failed ", class_config, class)); return (HXGE_ERROR | rs); } if (cfg.discard) ccfg |= HXGE_CLASS_DISCARD; if (cfg.lookup_enable) ccfg |= HXGE_CLASS_TCAM_LOOKUP; *class_config = ccfg; HXGE_DEBUG_MSG((hxgep, PFC_CTL, " ==> hxge_cfg_tcam_ip_class_get %x", ccfg)); return (HXGE_OK); } hxge_status_t hxge_pfc_ip_class_config_get(p_hxge_t hxgep, tcam_class_t class, uint32_t *config) { uint32_t t_class_config; int t_status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, PFC_CTL, " ==> hxge_pfc_ip_class_config_get")); t_class_config = 0; t_status = hxge_cfg_tcam_ip_class_get(hxgep, class, &t_class_config); if (t_status & HPI_PFC_ERROR) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_pfc_ip_class_config_get for class %d tcam failed", class)); return (t_status); } HXGE_DEBUG_MSG((hxgep, PFC_CTL, " hxge_pfc_ip_class_config tcam %x", t_class_config)); *config = t_class_config; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_pfc_ip_class_config_get")); return (HXGE_OK); } static hxge_status_t hxge_pfc_config_init(p_hxge_t hxgep) { hpi_handle_t handle; handle = hxgep->hpi_reg_handle; if (hxgep->hxge_hw_p == NULL) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_pfc_config_init: common hardware not set")); return (HXGE_ERROR); } (void) hpi_pfc_set_tcam_enable(handle, B_FALSE); (void) hpi_pfc_set_l2_hash(handle, B_FALSE); (void) hpi_pfc_set_tcp_cksum(handle, B_FALSE); (void) hpi_pfc_set_default_dma(handle, 0); (void) hpi_pfc_mac_addr_enable(handle, 0); (void) hpi_pfc_set_force_csum(handle, B_FALSE); /* Set the drop log mask to ignore the logs */ (void) hpi_pfc_set_drop_log_mask(handle, 1, 1, 1, 1, 1); /* Clear the interrupt masks to receive interrupts */ (void) hpi_pfc_set_interrupt_mask(handle, 0, 0, 0); /* Clear the interrupt status */ (void) hpi_pfc_clear_interrupt_status(handle); return (HXGE_OK); } static hxge_status_t hxge_pfc_tcam_invalidate_all(p_hxge_t hxgep) { hpi_status_t rs = HPI_SUCCESS; hpi_handle_t handle; p_hxge_hw_list_t hw_p; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_pfc_tcam_invalidate_all")); handle = hxgep->hpi_reg_handle; if ((hw_p = hxgep->hxge_hw_p) == NULL) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_pfc_tcam_invalidate_all: common hardware not set")); return (HXGE_ERROR); } MUTEX_ENTER(&hw_p->hxge_tcam_lock); rs = hpi_pfc_tcam_invalidate_all(handle); MUTEX_EXIT(&hw_p->hxge_tcam_lock); HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_pfc_tcam_invalidate_all")); if (rs != HPI_SUCCESS) return (HXGE_ERROR); return (HXGE_OK); } static hxge_status_t hxge_pfc_tcam_init(p_hxge_t hxgep) { hpi_status_t rs = HPI_SUCCESS; hpi_handle_t handle; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_pfc_tcam_init")); handle = hxgep->hpi_reg_handle; if (hxgep->hxge_hw_p == NULL) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_pfc_tcam_init: common hardware not set")); return (HXGE_ERROR); } /* * Disable the TCAM. */ rs = hpi_pfc_set_tcam_enable(handle, B_FALSE); if (rs != HPI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "failed TCAM Disable\n")); return (HXGE_ERROR | rs); } /* * Invalidate all the TCAM entries for this blade. */ rs = hxge_pfc_tcam_invalidate_all(hxgep); if (rs != HPI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "failed TCAM Disable\n")); return (HXGE_ERROR | rs); } HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_pfc_tcam_init")); return (HXGE_OK); } static hxge_status_t hxge_pfc_vlan_tbl_clear_all(p_hxge_t hxgep) { hpi_handle_t handle; hpi_status_t rs = HPI_SUCCESS; p_hxge_hw_list_t hw_p; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_pfc_vlan_tbl_clear_all ")); handle = hxgep->hpi_reg_handle; if ((hw_p = hxgep->hxge_hw_p) == NULL) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, " hxge_pfc_vlan_tbl_clear_all: common hardware not set")); return (HXGE_ERROR); } mutex_enter(&hw_p->hxge_vlan_lock); rs = hpi_pfc_cfg_vlan_table_clear(handle); mutex_exit(&hw_p->hxge_vlan_lock); if (rs != HPI_SUCCESS) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "failed vlan table clear\n")); return (HXGE_ERROR | rs); } HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_pfc_vlan_tbl_clear_all ")); return (HXGE_OK); } hxge_status_t hxge_pfc_ip_class_config(p_hxge_t hxgep, tcam_class_t class, uint32_t config) { uint32_t class_config; p_hxge_class_pt_cfg_t p_class_cfgp; tcam_key_cfg_t cfg; hpi_handle_t handle; hpi_status_t rs = HPI_SUCCESS; HXGE_DEBUG_MSG((hxgep, PFC_CTL, " ==> hxge_pfc_ip_class_config")); p_class_cfgp = (p_hxge_class_pt_cfg_t)&hxgep->class_config; class_config = p_class_cfgp->class_cfg[class]; if (class_config != config) { p_class_cfgp->class_cfg[class] = config; class_config = config; } handle = hxgep->hpi_reg_handle; if (class == TCAM_CLASS_ETYPE_1 || class == TCAM_CLASS_ETYPE_2) { rs = hpi_pfc_set_l2_class_slot(handle, class_config & HXGE_CLASS_ETHER_TYPE_MASK, class_config & HXGE_CLASS_VALID, class - TCAM_CLASS_ETYPE_1); } else { if (class_config & HXGE_CLASS_DISCARD) cfg.discard = 1; else cfg.discard = 0; if (class_config & HXGE_CLASS_TCAM_LOOKUP) cfg.lookup_enable = 1; else cfg.lookup_enable = 0; rs = hpi_pfc_set_l3_class_config(handle, class, cfg); } if (rs & HPI_PFC_ERROR) { HXGE_DEBUG_MSG((hxgep, PFC_CTL, " hxge_pfc_ip_class_config %x for class %d tcam failed", config, class)); return (HXGE_ERROR); } HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_pfc_ip_class_config")); return (HXGE_OK); } hxge_status_t hxge_pfc_ip_class_config_all(p_hxge_t hxgep) { uint32_t class_config; tcam_class_t cl; int status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_pfc_ip_class_config_all")); for (cl = TCAM_CLASS_ETYPE_1; cl <= TCAM_CLASS_SCTP_IPV6; cl++) { if (cl == TCAM_CLASS_RESERVED_4 || cl == TCAM_CLASS_RESERVED_5 || cl == TCAM_CLASS_RESERVED_6 || cl == TCAM_CLASS_RESERVED_7) continue; class_config = hxgep->class_config.class_cfg[cl]; status = hxge_pfc_ip_class_config(hxgep, cl, class_config); if (status & HPI_PFC_ERROR) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_pfc_ip_class_config failed " " class %d config %x ", cl, class_config)); } } HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_pfc_ip_class_config_all")); return (HXGE_OK); } static hxge_status_t hxge_pfc_update_hw(p_hxge_t hxgep) { hxge_status_t status = HXGE_OK; hpi_handle_t handle; p_hxge_param_t pa; uint64_t cfgd_vlans; uint64_t *val_ptr; int i; hxge_param_map_t *p_map; boolean_t parity = 0; boolean_t implicit_valid = 0; vlan_id_t implicit_vlan_id; p_hxge_mv_cfg_t vlan_table; p_hxge_class_pt_cfg_t p_class_cfgp; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_pfc_update_hw")); p_class_cfgp = (p_hxge_class_pt_cfg_t)&hxgep->class_config; handle = hxgep->hpi_reg_handle; status = hxge_pfc_set_hash(hxgep, p_class_cfgp->init_hash); if (status != HXGE_OK) { HXGE_DEBUG_MSG((hxgep, PFC_CTL, "hxge_pfc_set_hash Failed")); return (HXGE_ERROR); } vlan_table = p_class_cfgp->vlan_tbl; /* configure vlan tables */ pa = (p_hxge_param_t)&hxgep->param_arr[param_vlan_ids]; #if defined(__i386) val_ptr = (uint64_t *)(uint32_t)pa->value; #else val_ptr = (uint64_t *)pa->value; #endif cfgd_vlans = ((pa->type & HXGE_PARAM_ARRAY_CNT_MASK) >> HXGE_PARAM_ARRAY_CNT_SHIFT); for (i = 0; i < cfgd_vlans; i++) { p_map = (hxge_param_map_t *)&val_ptr[i]; if (vlan_table[p_map->param_id].flag) { status = hpi_pfc_cfg_vlan_table_entry_set(handle, p_map->param_id); if (status != HPI_SUCCESS) { HXGE_DEBUG_MSG((hxgep, PFC_CTL, "hpi_pfc_cfg_vlan_table_entry_set Failed")); return (HXGE_ERROR); } } } /* Configure the vlan_ctrl register */ /* Let hw generate the parity bits in pfc_vlan_table */ parity = 0; pa = (p_hxge_param_t)&hxgep->param_arr[param_implicit_vlan_id]; implicit_vlan_id = (vlan_id_t)pa->value; /* * Enable it only if there is a valid implicity vlan id either in * NDD table or the .conf file. */ if (implicit_vlan_id >= VLAN_ID_MIN && implicit_vlan_id <= VLAN_ID_MAX) implicit_valid = 1; status = hpi_pfc_cfg_vlan_control_set(handle, parity, implicit_valid, implicit_vlan_id); if (status != HPI_SUCCESS) { HXGE_DEBUG_MSG((hxgep, PFC_CTL, "hxge_pfc_update_hw: hpi_pfc_cfg_vlan_control_set failed")); return (HXGE_ERROR); } /* config MAC addresses */ /* Need to think about this */ /* Configure hash value and classes */ status = hxge_pfc_ip_class_config_all(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_pfc_ip_class_config_all Failed")); return (HXGE_ERROR); } return (HXGE_OK); } hxge_status_t hxge_pfc_hw_reset(p_hxge_t hxgep) { hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, PFC_CTL, " ==> hxge_pfc_hw_reset")); status = hxge_pfc_config_init(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "failed PFC config init.")); return (status); } status = hxge_pfc_tcam_init(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "failed TCAM init.")); return (status); } /* * invalidate VLAN RDC tables */ status = hxge_pfc_vlan_tbl_clear_all(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "failed VLAN Table Invalidate. ")); return (status); } hxgep->classifier.state |= HXGE_PFC_HW_RESET; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_pfc_hw_reset")); return (HXGE_OK); } hxge_status_t hxge_classify_init_hw(p_hxge_t hxgep) { hxge_status_t status = HXGE_OK; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_classify_init_hw")); if (hxgep->classifier.state & HXGE_PFC_HW_INIT) { HXGE_DEBUG_MSG((hxgep, PFC_CTL, "hxge_classify_init_hw already init")); return (HXGE_OK); } /* Now do a real configuration */ status = hxge_pfc_update_hw(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_pfc_update_hw failed")); return (HXGE_ERROR); } status = hxge_tcam_default_config(hxgep); if (status != HXGE_OK) { HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_tcam_default_config failed")); return (status); } hxgep->classifier.state |= HXGE_PFC_HW_INIT; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_classify_init_hw")); return (HXGE_OK); } hxge_status_t hxge_classify_init_sw(p_hxge_t hxgep) { int alloc_size; hxge_classify_t *classify_ptr; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_classify_init_sw")); classify_ptr = &hxgep->classifier; if (classify_ptr->state & HXGE_PFC_SW_INIT) { HXGE_DEBUG_MSG((hxgep, PFC_CTL, "hxge_classify_init_sw already init")); return (HXGE_OK); } /* Init SW structures */ classify_ptr->tcam_size = TCAM_HXGE_TCAM_MAX_ENTRY; alloc_size = sizeof (tcam_flow_spec_t) * classify_ptr->tcam_size; classify_ptr->tcam_entries = KMEM_ZALLOC(alloc_size, NULL); bzero(classify_ptr->class_usage, sizeof (classify_ptr->class_usage)); /* Start from the beginning of TCAM */ hxgep->classifier.tcam_location = 0; classify_ptr->state |= HXGE_PFC_SW_INIT; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_classify_init_sw")); return (HXGE_OK); } hxge_status_t hxge_classify_exit_sw(p_hxge_t hxgep) { int alloc_size; hxge_classify_t *classify_ptr; int fsize; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_classify_exit_sw")); classify_ptr = &hxgep->classifier; fsize = sizeof (tcam_flow_spec_t); if (classify_ptr->tcam_entries) { alloc_size = fsize * classify_ptr->tcam_size; KMEM_FREE((void *) classify_ptr->tcam_entries, alloc_size); } hxgep->classifier.state = NULL; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_classify_exit_sw")); return (HXGE_OK); } /*ARGSUSED*/ hxge_status_t hxge_pfc_handle_sys_errors(p_hxge_t hxgep) { return (HXGE_OK); } uint_t hxge_pfc_intr(caddr_t arg1, caddr_t arg2) { p_hxge_ldv_t ldvp = (p_hxge_ldv_t)arg1; p_hxge_t hxgep = (p_hxge_t)arg2; hpi_handle_t handle; p_hxge_pfc_stats_t statsp; pfc_int_status_t int_status; pfc_bad_cs_counter_t bad_cs_count; pfc_drop_counter_t drop_count; pfc_drop_log_t drop_log; pfc_vlan_par_err_log_t vlan_par_err_log; pfc_tcam_par_err_log_t tcam_par_err_log; if (ldvp == NULL) { HXGE_DEBUG_MSG((NULL, INT_CTL, "<== hxge_pfc_intr: hxgep $%p ldvp $%p", hxgep, ldvp)); return (DDI_INTR_UNCLAIMED); } if (arg2 == NULL || (void *) ldvp->hxgep != arg2) { hxgep = ldvp->hxgep; } handle = hxgep->hpi_reg_handle; statsp = (p_hxge_pfc_stats_t)&hxgep->statsp->pfc_stats; /* * need to read the pfc interrupt status register to figure out * what is happenning */ (void) hpi_pfc_get_interrupt_status(handle, &int_status); if (int_status.bits.pkt_drop) { statsp->pkt_drop++; if (statsp->pkt_drop == 1) HXGE_ERROR_MSG((hxgep, INT_CTL, "PFC pkt_drop")); /* Collect each individual drops */ (void) hpi_pfc_get_drop_log(handle, &drop_log); if (drop_log.bits.tcp_ctrl_drop) statsp->errlog.tcp_ctrl_drop++; if (drop_log.bits.l2_addr_drop) statsp->errlog.l2_addr_drop++; if (drop_log.bits.class_code_drop) statsp->errlog.class_code_drop++; if (drop_log.bits.tcam_drop) statsp->errlog.tcam_drop++; if (drop_log.bits.vlan_drop) statsp->errlog.vlan_drop++; /* Collect the total drops for all kinds */ (void) hpi_pfc_get_drop_counter(handle, &drop_count.value); statsp->drop_count += drop_count.bits.drop_count; } if (int_status.bits.tcam_parity_err) { statsp->tcam_parity_err++; (void) hpi_pfc_get_tcam_parity_log(handle, &tcam_par_err_log); statsp->errlog.tcam_par_err_log = tcam_par_err_log.bits.addr; if (statsp->tcam_parity_err == 1) HXGE_ERROR_MSG((hxgep, INT_CTL, " TCAM parity error addr: 0x%x", tcam_par_err_log.bits.addr)); } if (int_status.bits.vlan_parity_err) { statsp->vlan_parity_err++; (void) hpi_pfc_get_vlan_parity_log(handle, &vlan_par_err_log); statsp->errlog.vlan_par_err_log = vlan_par_err_log.bits.addr; if (statsp->vlan_parity_err == 1) HXGE_ERROR_MSG((hxgep, INT_CTL, " vlan table parity error addr: 0x%x", vlan_par_err_log.bits.addr)); } (void) hpi_pfc_get_bad_csum_counter(handle, &bad_cs_count.value); statsp->bad_cs_count += bad_cs_count.bits.bad_cs_count; (void) hpi_pfc_clear_interrupt_status(handle); return (DDI_INTR_CLAIMED); } static void hxge_pfc_get_next_mac_addr(uint8_t *st_mac, struct ether_addr *final_mac) { uint64_t mac[ETHERADDRL]; uint64_t mac_addr = 0; int i, j; for (i = ETHERADDRL - 1, j = 0; j < ETHERADDRL; i--, j++) { mac[j] = st_mac[i]; mac_addr |= (mac[j] << (j*8)); } final_mac->ether_addr_octet[0] = (mac_addr & 0xff0000000000) >> 40; final_mac->ether_addr_octet[1] = (mac_addr & 0xff00000000) >> 32; final_mac->ether_addr_octet[2] = (mac_addr & 0xff000000) >> 24; final_mac->ether_addr_octet[3] = (mac_addr & 0xff0000) >> 16; final_mac->ether_addr_octet[4] = (mac_addr & 0xff00) >> 8; final_mac->ether_addr_octet[5] = (mac_addr & 0xff); } hxge_status_t hxge_pfc_mac_addrs_get(p_hxge_t hxgep) { hxge_status_t status = HXGE_OK; hpi_status_t hpi_status = HPI_SUCCESS; hpi_handle_t handle = HXGE_DEV_HPI_HANDLE(hxgep); uint8_t mac_addr[ETHERADDRL]; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_pfc_mac_addr_get")); hpi_status = hpi_pfc_mac_addr_get_i(handle, mac_addr, 0); if (hpi_status != HPI_SUCCESS) { status = (HXGE_ERROR | hpi_status); HXGE_ERROR_MSG((hxgep, HXGE_ERR_CTL, "hxge_pfc_mac_addr_get: pfc_mac_addr_get_i failed")); goto exit; } hxge_pfc_get_next_mac_addr(mac_addr, &hxgep->factaddr); HXGE_ERROR_MSG((hxgep, PFC_CTL, "MAC Addr(0): %x:%x:%x:%x:%x:%x\n", mac_addr[0], mac_addr[1], mac_addr[2], mac_addr[3], mac_addr[4], mac_addr[5])); exit: HXGE_DEBUG_MSG((hxgep, CFG_CTL, "<== hxge_pfc_mac_addr_get, " "status [0x%x]", status)); return (status); } /* * Calculate the bit in the multicast address filter * that selects the given * address. * Note: For Hydra, the last 8-bits are used. */ static uint32_t crc32_mchash(p_ether_addr_t addr) { uint8_t *cp; uint32_t crc; uint32_t c; int byte; int bit; cp = (uint8_t *)addr; crc = (uint32_t)0xffffffff; for (byte = 0; byte < ETHERADDRL; byte++) { /* Hydra calculates the hash backwardly */ c = (uint32_t)cp[ETHERADDRL - 1 - byte]; for (bit = 0; bit < 8; bit++) { if ((c & 0x1) ^ (crc & 0x1)) crc = (crc >> 1)^0xedb88320; else crc = (crc >> 1); c >>= 1; } } return ((~crc) >> (32 - HASH_BITS)); } static hxge_status_t hxge_pfc_load_hash_table(p_hxge_t hxgep) { uint32_t i; uint16_t hashtab_e; p_hash_filter_t hash_filter; hpi_handle_t handle; HXGE_DEBUG_MSG((hxgep, PFC_CTL, "==> hxge_pfc_load_hash_table\n")); handle = hxgep->hpi_reg_handle; /* * Load the multicast hash filter bits. */ hash_filter = hxgep->hash_filter; for (i = 0; i < MAC_MAX_HASH_ENTRY; i++) { if (hash_filter != NULL) { hashtab_e = (uint16_t)hash_filter->hash_filter_regs[i]; } else { hashtab_e = 0; } if (hpi_pfc_set_multicast_hash_table(handle, i, hashtab_e) != HPI_SUCCESS) return (HXGE_ERROR); } HXGE_DEBUG_MSG((hxgep, PFC_CTL, "<== hxge_pfc_load_hash_table\n")); return (HXGE_OK); }