/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #include #include #include #include #include #include #include #include /* * Ethernet administration library. */ /* * kstat names for extracting attributes. */ typedef struct ether_spdx_s { dladm_ether_spdx_t eth_spdx; char *eth_spdx_stat_name; } ether_spdx_t; static ether_spdx_t cap_spdx[] = { {{1000, LINK_DUPLEX_FULL}, "cap_1000fdx"}, {{1000, LINK_DUPLEX_HALF}, "cap_1000hdx"}, {{100, LINK_DUPLEX_FULL}, "cap_100fdx"}, {{100, LINK_DUPLEX_HALF}, "cap_100hdx"}, {{10, LINK_DUPLEX_FULL}, "cap_10fdx"}, {{10, LINK_DUPLEX_HALF}, "cap_10hdx"}, {{0, LINK_DUPLEX_UNKNOWN}, NULL} }; static ether_spdx_t adv_cap_spdx[] = { {{1000, LINK_DUPLEX_FULL}, "adv_cap_1000fdx"}, {{1000, LINK_DUPLEX_HALF}, "adv_cap_1000hdx"}, {{100, LINK_DUPLEX_FULL}, "adv_cap_100fdx"}, {{100, LINK_DUPLEX_HALF}, "adv_cap_100hdx"}, {{10, LINK_DUPLEX_FULL}, "adv_cap_10fdx"}, {{10, LINK_DUPLEX_HALF}, "adv_cap_10hdx"}, {{0, LINK_DUPLEX_UNKNOWN}, NULL} }; static ether_spdx_t lp_cap_spdx[] = { {{1000, LINK_DUPLEX_FULL}, "lp_cap_1000fdx"}, {{1000, LINK_DUPLEX_HALF}, "lp_cap_1000hdx"}, {{100, LINK_DUPLEX_FULL}, "lp_cap_100fdx"}, {{100, LINK_DUPLEX_HALF}, "lp_cap_100hdx"}, {{10, LINK_DUPLEX_FULL}, "lp_cap_10fdx"}, {{10, LINK_DUPLEX_HALF}, "lp_cap_10hdx"}, {{0, LINK_DUPLEX_UNKNOWN}, NULL} }; typedef struct attr_kstat_s { char *autoneg_stat; char *pause_stat; char *asmpause_stat; char *fault_stat; ether_spdx_t *spdx_stat; } attr_kstat_t; static attr_kstat_t attrstat[] = { {"link_autoneg", /* current */ "link_pause", "link_asmpause", NULL, NULL}, {"cap_autoneg", /* capable */ "cap_pause", "cap_asmpause", "cap_rem_fault", cap_spdx}, {"adv_cap_autoneg", /* advertised */ "adv_cap_pause", "adv_cap_asmpause", "adv_rem_fault", adv_cap_spdx}, {"lp_cap_autoneg", /* peer advertised */ "lp_cap_pause", "lp_cap_asmpause", "lp_rem_fault", lp_cap_spdx} }; /* * Get the speed-duplex stats specified in the ether_spdx_t table passed in * by querying the appropriate kstat for each entry in the table. */ static dladm_status_t i_dladm_get_spdx(datalink_id_t linkid, dladm_ether_attr_t *eattr, ether_spdx_t *spdx_stat) { int i, nspdx = 0; uint32_t speed; dladm_status_t status; void *ptr; eattr->le_spdx = NULL; for (i = 0; spdx_stat[i].eth_spdx_stat_name != NULL; i++) { if ((status = dladm_get_single_mac_stat(linkid, spdx_stat[i].eth_spdx_stat_name, KSTAT_DATA_UINT32, &speed)) != DLADM_STATUS_OK) { if (status == DLADM_STATUS_NOTFOUND) { /* * Missing statistic. * Skip this one and try the rest. */ continue; } else { free(eattr->le_spdx); eattr->le_num_spdx = 0; return (status); } } if (speed == 0) continue; nspdx++; ptr = realloc(eattr->le_spdx, nspdx * sizeof (dladm_ether_spdx_t)); if (ptr != NULL) { eattr->le_spdx = ptr; } else { free(eattr->le_spdx); eattr->le_num_spdx = 0; return (DLADM_STATUS_NOMEM); } eattr->le_spdx[nspdx - 1] = spdx_stat[i].eth_spdx; } eattr->le_num_spdx = nspdx; return (DLADM_STATUS_OK); } /* * Returns "yes" or "no" based on the autonegotion capabilities * for the parameter type indicated by ptype. The permissible * values for ptype are CURRENT, CAPABLE, ADV, PEERADV. */ char * dladm_ether_autoneg2str(char *buf, size_t buflen, dladm_ether_info_t *eattr, int ptype) { boolean_t autoneg = eattr->lei_attr[ptype].le_autoneg; (void) strlcpy(buf, (autoneg ? "yes" : "no"), buflen); return (buf); } /* * Returns {"bi", "tx", "none"} based on the flow-control capabilities * for the parameter type indicated by ptype. The permissible * values for ptype are CURRENT, CAPABLE, ADV, PEERADV. */ char * dladm_ether_pause2str(char *buf, size_t buflen, dladm_ether_info_t *eattr, int ptype) { boolean_t pause = eattr->lei_attr[ptype].le_pause; boolean_t asmpause = eattr->lei_attr[ptype].le_asmpause; if (pause) (void) strlcpy(buf, "bi", buflen); else if (asmpause) (void) strlcpy(buf, "tx", buflen); else (void) strlcpy(buf, "none", buflen); return (buf); } /* * For a given param type, parse the list of speed-duplex pairs in * the dladm_ether_info_t and return a comma-separated string formatted * as - where is the value of * speed, in units specifid by the which is one * of 'M' (Mbits/sec) or 'G' (Gigabits/sec). The permissible values of * are 'u' (indicating duplex is "unknown") or one/both of * 'f', 'h' (indicating full-duplex and half-duplex respectively) */ extern char * dladm_ether_spdx2str(char *buf, size_t buflen, dladm_ether_info_t *eattr, int ptype) { int i, j; boolean_t is_full, is_half; int speed; char speed_unit; char tmpbuf[DLADM_STRSIZE]; dladm_ether_spdx_t *spdx; uint32_t nspdx; spdx = eattr->lei_attr[ptype].le_spdx; nspdx = eattr->lei_attr[ptype].le_num_spdx; for (i = 0; i < nspdx; i++) { speed = spdx[i].lesd_speed; /* * if we have already covered this speed for * the -duplex case before this, skip it */ for (j = 0; j < i; j++) { if (speed == spdx[j].lesd_speed) break; } if (j < i) continue; if (speed >= 1000) { speed = speed/1000; speed_unit = 'G'; } else { speed_unit = 'M'; } (void) snprintf(tmpbuf, DLADM_STRSIZE, "%d%c", speed, speed_unit); if (i > 0) (void) strncat(buf, ",", buflen); (void) strncat(buf, tmpbuf, buflen); is_full = is_half = B_FALSE; /* * Find all the supported duplex values for this speed. */ for (j = 0; j < nspdx; j++) { if (spdx[j].lesd_speed != spdx[i].lesd_speed) continue; if (spdx[j].lesd_duplex == LINK_DUPLEX_FULL) is_full = B_TRUE; if (spdx[j].lesd_duplex == LINK_DUPLEX_HALF) is_half = B_TRUE; } if (is_full && is_half) (void) strncat(buf, "-fh", buflen); else if (is_full) (void) strncat(buf, "-f", buflen); else if (is_half) (void) strncat(buf, "-h", buflen); } return (buf); } /* * Extract Ethernet attributes of the link specified by linkid. * Information for the CURRENT, CAPABLE, ADV and PEERADV parameter * types is extracted into the lei_attr[] entries in the dladm_ether_info_t. * On succesful return, the memory allocated in this function should be * freed by calling dladm_ether_info_done(). */ extern dladm_status_t dladm_ether_info(datalink_id_t linkid, dladm_ether_info_t *eattr) { uint32_t autoneg, pause, asmpause, fault; uint64_t sp64; dladm_status_t status; int i; link_duplex_t link_duplex; bzero(eattr, sizeof (*eattr)); status = dladm_datalink_id2info(linkid, NULL, NULL, NULL, eattr->lei_linkname, sizeof (eattr->lei_linkname)); if (status != DLADM_STATUS_OK) goto bail; /* get current values of speed, duplex, state of link */ eattr->lei_attr[CURRENT].le_num_spdx = 1; eattr->lei_attr[CURRENT].le_spdx = malloc(sizeof (dladm_ether_spdx_t)); if (eattr->lei_attr[CURRENT].le_spdx == NULL) { status = DLADM_STATUS_NOMEM; goto bail; } if ((status = dladm_get_single_mac_stat(linkid, "ifspeed", KSTAT_DATA_UINT64, &sp64)) != DLADM_STATUS_OK) goto bail; if ((status = dladm_get_single_mac_stat(linkid, "link_duplex", KSTAT_DATA_UINT32, &link_duplex)) != DLADM_STATUS_OK) goto bail; eattr->lei_attr[CURRENT].le_spdx->lesd_speed = (int)(sp64/1000000ull); eattr->lei_attr[CURRENT].le_spdx->lesd_duplex = link_duplex; status = i_dladm_get_state(linkid, &eattr->lei_state); if (status != DLADM_STATUS_OK) goto bail; /* get the auto, pause, asmpause, fault values */ for (i = CURRENT; i <= PEERADV; i++) { status = dladm_get_single_mac_stat(linkid, attrstat[i].autoneg_stat, KSTAT_DATA_UINT32, &autoneg); if (status != DLADM_STATUS_OK) goto bail; status = dladm_get_single_mac_stat(linkid, attrstat[i].pause_stat, KSTAT_DATA_UINT32, &pause); if (status != DLADM_STATUS_OK) goto bail; status = dladm_get_single_mac_stat(linkid, attrstat[i].asmpause_stat, KSTAT_DATA_UINT32, &asmpause); if (status != DLADM_STATUS_OK) goto bail; eattr->lei_attr[i].le_autoneg = (autoneg != 0); eattr->lei_attr[i].le_pause = (pause != 0); eattr->lei_attr[i].le_asmpause = (asmpause != 0); if (i == CURRENT) continue; status = dladm_get_single_mac_stat(linkid, attrstat[i].fault_stat, KSTAT_DATA_UINT32, &fault); if (status != DLADM_STATUS_OK) goto bail; eattr->lei_attr[i].le_fault = (pause != 0); /* get all the supported speed/duplex values */ status = i_dladm_get_spdx(linkid, &eattr->lei_attr[i], attrstat[i].spdx_stat); if (status != DLADM_STATUS_OK) goto bail; } eattr->lei_attr[CURRENT].le_fault = eattr->lei_attr[ADV].le_fault || eattr->lei_attr[PEERADV].le_fault; bail: if (status != DLADM_STATUS_OK) dladm_ether_info_done(eattr); return (status); } extern void dladm_ether_info_done(dladm_ether_info_t *eattr) { int i; for (i = CURRENT; i <= PEERADV; i++) free(eattr->lei_attr[i].le_spdx); }