/* libmii.c: MII diagnostic and setup library. Copyright 1997-2003 by Donald Becker. This version released under the Gnu General Public License, incorporated herein by reference. This source code may be distributed without modification using the existing notice. Any modification to this source code must include a full notice as described in the GPL Contact the author for use under other terms. The author may be reached as becker@scyld.com, or C/O Scyld Computing Corporation 914 Bay Ridge Road, Suite 220 Annapolis MD 21403 References http://www.scyld.com/expert/NWay.html http://www.national.com/pf/DP/DP83840A.html */ static const char version_msg[] = "libmii.c:v2.11 2/28/2005 Donald Becker (becker@scyld.com)\n" " http://www.scyld.com/diag/index.html\n"; /* This library exports the following functions: IOADDR: A token passed to the mdio_read() function. PHY_ID: The MII transceiver address, passed uninterpreted to mdio_read(). */ void show_mii_details(long ioaddr, int phy_id); int monitor_mii(long ioaddr, int phy_id); /* This library expects to be able to call the following functions: */ extern int mdio_read(long ioaddr, int phy_id, int mii_reg_num); extern void mdio_write(long ioaddr, int phy_id, int mii_reg_num, int value); #include #include #include #include #include #include #include typedef u_int32_t u32; typedef u_int16_t u16; typedef u_int8_t u8; static const char *media_names[] = { "10baseT", "10baseT-FD", "100baseTx", "100baseTx-FD", "100baseT4", "Pause", "AsymPause", 0, }; static void ns83843(long ioaddr, int phy_id); static void qs6612(long ioaddr, int phy_id); static void smsc83c180(long ioaddr, int phy_id); static void tdk78q2120(long ioaddr, int phy_id); static void davicom_dm9101(long ioaddr, int phy_id); static void intel_i553(long ioaddr, int phy_id); static void enablesemi(long ioaddr, int phy_id); static void amd_pna(long ioaddr, int phy_id); static void amd_tx(long ioaddr, int phy_id); static void admtek(long ioaddr, int phy_id); static void lu3x31(long ioaddr, int phy_id); static void myson981(long ioaddr, int phy_id); static void via_tahoe(long ioaddr, int phy_id); static void via_vt6103(long ioaddr, int phy_id); static void via_vt6105(long ioaddr, int phy_id); static void intel(long ioaddr, int phy_id); static void mv88x3310_xs(long ioaddr, int phy_id); static void mv88x3310(long ioaddr, int phy_id); static void mv88e1111(long ioaddr, int phy_id); static void mv88e151x(long ioaddr, int phy_id); enum { MDIO_MMD_PMAPMD = 1, MDIO_MMD_WIS = 2, MDIO_MMD_PCS = 3, MDIO_MMD_PHY_XS = 4, MDIO_MMD_DTE_XS = 5, MDIO_MMD_TC = 6, MDIO_MMD_AN = 7, MDIO_MMD_VENDOR1 = 30, MDIO_MMD_VENDOR2 = 31, MMD_CTRL1 = 0, MMD_STAT1 = 1, MMD_DEVID1 = 2, MMD_DEVID2 = 3, MMD_SPEED = 4, MMD_DEVPKG1 = 5, MMD_DEVPKG2 = 6, MMD_CTRL2 = 7, MMD_STAT2 = 8, MMD_PKGID1 = 14, MMD_PKGID2 = 15, MMD_PMA_EXT_ABL = 11, MMD_PMA_40G100G_EXT_ABL = 13, MMD_PMA_EEE_CAPABILITY = 16, MMD_PMA_25G_EXT_ABL = 19, MMD_PMA_NBASE_EXT_ABL = 21, MMD_PMA_10GBT_STATUS = 129, MMD_PMA_10GBT_SWAPPOL = 130, MMD_PCS_EEE_CTRL_CAPAB = 20, MMD_PCS_EEE_WAKE_ERR = 22, MMD_PCS_BASERT_STAT1 = 32, MMD_PCS_BASERT_STAT2 = 33, MMD_PHY_XS_EEE_CAPAB = 20, MMD_PHY_XS_EEE_WAKE_ERR = 22, MMD_PHY_XS_LANE_STATUS = 24, MMD_DTE_XS_EEE_CAPAB = 20, MMD_DTE_XS_EEE_WAKE_ERR = 22, MMD_AN_BASE_ADV0 = 16, MMD_AN_BASE_ADV1 = 17, MMD_AN_BASE_ADV2 = 18, MMD_AN_BASE_LPA0 = 19, MMD_AN_BASE_LPA1 = 20, MMD_AN_BASE_LPA2 = 21, MMD_AN_XNP_ADV0 = 22, MMD_AN_XNP_ADV1 = 23, MMD_AN_XNP_ADV2 = 24, MMD_AN_XNP_LPA0 = 25, MMD_AN_XNP_LPA1 = 26, MMD_AN_XNP_LPA2 = 27, MMD_AN_MULTI_GBT_CTRL = 32, MMD_AN_MULTI_GBT_STAT = 33, MMD_AN_BASER_STAT = 48, MMD_AN_EEE_ADV = 60, MMD_AN_EEE_LPA = 61, }; #define BIT(x) (1 << (x)) static const char *mmd_name[32] = { [MDIO_MMD_PMAPMD] = "PMA/PMD", [MDIO_MMD_WIS] = "WIS", [MDIO_MMD_PCS] = "PCS", [MDIO_MMD_PHY_XS] = "PHY XS", [MDIO_MMD_DTE_XS] = "DTE XS", [MDIO_MMD_TC] = "TC", [MDIO_MMD_AN] = "AN", [MDIO_MMD_VENDOR1] = "Vendor Specific 1", [MDIO_MMD_VENDOR2] = "Vendor Specific 2", }; struct phy { long ioaddr; int phy_id; int devad; unsigned int page; unsigned int offset; int (*mdio_read)(const struct phy *phy, unsigned int reg); }; #define DEFINE_C22_PHY(name, addr, id) \ struct phy name = { \ .ioaddr = addr, \ .phy_id = id, \ .mdio_read = __mdio_read_phy, \ } #define DEFINE_C45_PHY(name, addr, id, __devad) \ struct phy name = { \ .ioaddr = addr, \ .phy_id = id, \ .devad = __devad, \ .mdio_read = __mdio_read_phy, \ } struct c22_decoder { void (*show_advert)(struct phy *phy, u16 *regs); void (*show_lpar)(struct phy *phy, u16 *regs); }; struct mii_partnum { u32 phy_id; /* Vendor ID */ u32 msk_id; /* Vendor ID mask */ const char *vendor; /* Vendor name. */ void (*(func))(long xcvr_if, int phy_id);/* Function to emit more info. */ } static oui_map[] = { #define OUI(a,b,c) ((a) << 26 | (b) << 18 | (c) << 10), 0xfffffc00 /* Table sorted in numerical order, but with regard to the mask */ {0x00000000, 0xffffffff, "Unknown transceiver type"}, {0x00006b91, 0xffffffff, "AMD 79c901A.1 HomePNA", amd_pna }, {0x00006b92, 0xffffffff, "AMD 79c901A.2 HomePNA", amd_pna }, {0x00006b93, 0xffffffff, "AMD 79c901A.3 HomePNA", amd_pna }, {0x00007b71, 0xffffffff, "AMD 79c901A.3 10baseT", amd_tx }, {0x00221720, 0xffffffff, "Alta/Kendin Sundance"}, {OUI(0x00, 0x08, 0x85), "Alta/Kendin Sundance"}, {0x002b09a0, 0xfffffff0, "Marvell Semiconductor 88X3310", mv88x3310 }, {0x002bdc00, 0xfffffc00, "Broadcom BCM63XX"}, {0x00406000, 0xfffffc00, "Broadcom BCM63XX"}, {0x00437411, 0xffffffff, "Enable Semiconductor EL40-331", enablesemi }, {0x004dd076, 0xffffffef, "Atheros AT8030"}, {0x004dd074, 0xffffffef, "Atheros AT8031"}, {0x004dd072, 0xffffffef, "Atheros AT8035"}, {0x01018f20, 0xffffffff, "VIA Tahoe VT6103", via_vt6103 }, {0x01018f30, 0xffffffff, "VIA Tahoe VT6104", via_tahoe }, {0x01018f22, 0xffffffff, "VIA Rhine VT6105", via_vt6105 }, {0x01410c60, 0xfffffff0, "Marvell Semiconductor 88E1101"}, {0x01410c90, 0xfffffff0, "Marvell Semiconductor 88E1112"}, {0x01410cb0, 0xfffffff0, "Marvell Semiconductor 88E1121R"}, {0x01410cc0, 0xfffffff0, "Marvell Semiconductor 88E1111", mv88e1111 }, {0x01410cd0, 0xfffffff0, "Marvell Semiconductor 88E1145"}, {0x01410da0, 0xfffffff0, "Marvell Semiconductor 88X3310", mv88x3310_xs}, {0x01410dd0, 0xfffffff0, "Marvell Semiconductor 88E151x", mv88e151x }, {0x01410e10, 0xfffffff0, "Marvell Semiconductor 88E1118"}, {0x01410e30, 0xfffffff0, "Marvell Semiconductor 88E1240"}, {0x01410e40, 0xfffffff0, "Marvell Semiconductor 88E1116R"}, {0x01410e50, 0xfffffff0, "Marvell Semiconductor 88E1149R"}, {0x01410e60, 0xfffffff0, "Marvell Semiconductor 88E3016"}, {0x01410e90, 0xfffffff0, "Marvell Semiconductor 88E1318S"}, {0x01410ea0, 0xfffffff0, "Marvell Semiconductor 88E1545"}, {0x01410eb0, 0xfffffff0, "Marvell Semiconductor 88E1540"}, {OUI(0x00, 0x50, 0x43), "Marvell Semiconductor (unknown type)"}, {0x0143bc30, 0xfffffff0, "Broadcom BCM5241"}, {0x0143bc70, 0xfffffff0, "Broadcom BCMAC131"}, {0x0143bca0, 0xfffffff0, "Broadcom BCM5481"}, {0x0143bcf0, 0xfffffff0, "Broadcom BCM5395"}, {0x0143bd60, 0xfffffff0, "Broadcom BCM50610"}, {0x0143bd70, 0xfffffff0, "Broadcom BCM50610M"}, {0x01814410, 0xffffffff, "Quality Semiconductor QS6612", qs6612 }, {OUI(0x00, 0x60, 0x51), "Quality Semiconductor (unknown type)" }, {0x0181b800, 0xffffffff, "Davicom DM9101", davicom_dm9101 }, {OUI(0x00, 0x60, 0x6e), "Davicom (unknown type)", davicom_dm9101 }, {0x02821c51, 0xffffffff, "SMSC 83c180", smsc83c180 }, {0x02a80150, 0xffffffff, "Intel 82557 series", intel }, {0x02a80151, 0xffffffff, "Intel 82555 rev 1", intel }, {0x02a80154, 0xffffffff, "Intel 82559 transceiver", intel }, {OUI(0x00, 0xaa, 0x00), "Intel 82555 series transceiver", intel }, {0x0300e542, 0xffffffff, "TDK Semi 78Q2120 rev. 2", tdk78q2120 }, {0x0300e543, 0xffffffff, "TDK Semi 78Q2120 rev. 3", tdk78q2120 }, {0x0300e54b, 0xffffffff, "TDK Semi 78Q2120 rev. 11", tdk78q2120 }, {OUI(0x00, 0xc0, 0x39), "TDK transceiver (unknown type)", tdk78q2120 }, {0x0302d000, 0xffffffff, "Myson MTD981", myson981 }, {OUI(0x00, 0xc0, 0xb4), "Myson (unknown type)", myson981 }, {OUI(0x00, 0xf8, 0x00), "Intel (unknown type)", intel_i553 }, {0x20005c01, 0xffffffff, "National Semiconductor 83840A"}, {0x20005c10, 0xffffffff, "National Semiconductor 83843", ns83843 }, {0x600d8480, 0xfffffff0, "Broadcom BCM7439"}, {0x600d8490, 0xfffffff0, "Broadcom BCM7366"}, {0x600d84b0, 0xfffffff0, "Broadcom BCM7362"}, {0x600d8510, 0xfffffff0, "Broadcom BCM7445"}, {0x600d8650, 0xfffffff0, "Broadcom BCM7346"}, {0x600d86b0, 0xfffffff0, "Broadcom BCM7425"}, {0x600d8730, 0xfffffff0, "Broadcom BCM7429"}, {0x600d8750, 0xfffffff0, "Broadcom BCM7435"}, {0x78100000, 0xffffffff, "Level One LXT970"}, {0x78100001, 0xffffffff, "Level One LXT971"}, {0x78100003, 0xffffffff, "Level One LXT971A"}, {OUI(0x1e, 0x04, 0x00), "Level One (unknown type)"}, {0xae025080, 0xfffffff0, "Broadcom BCM7439"}, {0xae025090, 0xfffffff0, "Broadcom BCM7268"}, {0xae025190, 0xfffffff0, "Broadcom BCM7260"}, {0xae0251a0, 0xfffffff0, "Broadcom BCM7278"}, {0xae025260, 0xfffffff0, "Broadcom BCM7364"}, {0xae025280, 0xfffffff0, "Broadcom BCM7250"}, {0xae0252e0, 0xfffffff0, "Broadcom BCM74371"}, {0xae0253b0, 0xfffffff0, "Broadcom BCM7271"}, /* Unsorted entries */ {0x0022561b, 0xffffffff, "AdHoc Technology AH101LF", tdk78q2120 }, {0x00225523, 0xffffffff, "Altimata Communications AC101LF", tdk78q2120 }, {OUI(0x00, 0x10, 0xa9), "Altimata Comm (unknown type)", tdk78q2120 }, {OUI(0x00, 0xc0, 0xb4), "ASIX (unknown type)", tdk78q2120 }, {0x00225410, 0xffffffff, "ADMtek AN983 Comet", admtek }, {0x00225513, 0xffffffff, "ADMtek AN985 Comet", admtek }, {OUI(0x00, 0xe0, 0x92), "ADMtek (unknown type)", admtek }, {0x01807641, 0xffffffff, "Lucent LU6612", qs6612 }, {0x00437411, 0xffffffff, "Lucent LU3X31", lu3x31 }, {OUI(0x00, 0xa0, 0x7d), "LSI Logic (Seeq) 80225"}, {0, }, }; static int __mdio_read_phy(const struct phy *phy, unsigned int reg) { return mdio_read(phy->ioaddr, phy->phy_id | phy->devad, phy->offset + reg); } static int mdio_read_phy(const struct phy *phy, unsigned int reg) { return phy->mdio_read(phy, reg); } static int lookup_vendor(int reg2, int reg3) { u32 id = reg2 << 16 | reg3; unsigned char oui_0 = id >> 26; unsigned char oui_1 = id >> 18; unsigned char oui_2 = id >> 10; unsigned char model = (id >> 4) & 0x3f; unsigned char rev = id & 0x0f; int i, vendor = 0; printf(" Vendor ID is %2.2x:%2.2x:%2.2x:--:--:--, model %d rev. %d.\n", oui_0, oui_1, oui_2, model, rev); for (i = 0; oui_map[i].vendor; i++) if (((oui_map[i].phy_id ^ id) & oui_map[i].msk_id) == 0) { printf(" Vendor/Part: %s.\n", oui_map[i].vendor); vendor = i; break; } if (oui_map[i].vendor == NULL) printf(" No specific information is known about this transceiver" " type.\n"); return vendor; } struct msg_tbl { int bitmask; char *msg; }; static void msg_if_set(const int val, const struct msg_tbl msg_tbl[]) { int i; for (i = 0; msg_tbl[i].bitmask; i++) if (msg_tbl[i].bitmask & val) printf(" %s\n", msg_tbl[i].msg); } static void msg_if_set_fmt(const int val, const struct msg_tbl msg_tbl[], const char *fmt) { int i; for (i = 0; msg_tbl[i].bitmask; i++) if (msg_tbl[i].bitmask & val) printf(fmt, msg_tbl[i].msg); } static u16 mii_val[64], c45_an_ctrl; void read_mii_regs(long ioaddr, int phy_id, unsigned int first, unsigned int num_regs) { int mii_reg; for (mii_reg = 0; mii_reg < num_regs; mii_reg++) { int val = mdio_read(ioaddr, phy_id, first + mii_reg); mii_val[mii_reg] = val < 0 ? 0 : val; } } static void show_mii_regs(int num_regs) { int mii_reg; for (mii_reg = 0; mii_reg < num_regs; mii_reg++) printf("%s %4.4x", (mii_reg % 8) == 0 ? "\n " : "", mii_val[mii_reg]); } struct bit_decoder { u16 mask; u16 val; const char *str; }; static const char **bit_decoder(const char **str, u16 val, const struct bit_decoder *decoder) { int i; for (i = 0; decoder[i].str; i++) if ((val & decoder[i].mask) == decoder[i].val) *str++ = decoder[i].str; *str = NULL; return str; } struct multi_bit_decoder { unsigned int offset; const struct bit_decoder *bits; }; static const char **multi_bit_decoder(const char **str, const u16 *vals, const struct multi_bit_decoder *mdec) { const char **p = str; int i; for (i = 0; mdec[i].bits; i++) p = bit_decoder(p, vals[mdec[i].offset], mdec[i].bits); return p; } #if 0 static char *strconcat(const char *separator, const char **strings) { size_t length, sep_length = strlen(separator); char *string, *p; int i; if (!strings[0]) return NULL; for (i = 0, length = 0; strings[i]; i++) length += strlen(strings[i]); length += (i - 1) * sep_length; string = malloc(length); if (!string) return NULL; for (i = 0, p = string; strings[i]; i++) { if (i) { strcpy(p, separator); p += sep_length; } strcpy(p, strings[i]); p += strlen(p); } return string; } #endif static void print_strings(const char **strs, const char *prefix, const char *separator) { int need_separator = 0; int need_prefix = 1; int i; for (i = 0; strs[i]; i++) { const char *pfx = ""; const char *str = strs[i]; if (need_prefix) { pfx = prefix; need_prefix = 0; } else if (need_separator) { pfx = separator; } printf("%s%s", pfx, str); if (str[strlen(str) - 1] == '\n') need_prefix = 1; need_separator = 1; } if (!need_separator || !need_prefix) printf(".\n"); } static void show_mii_bits(u16 val, const struct bit_decoder *decoder, const char *prefix, const char *separator) { const char *strings[64]; bit_decoder(strings, val, decoder); print_strings(strings, prefix, separator); } static void show_mii_reg(const char *name, u16 val, const struct bit_decoder *decoder, const char *prefix, const char *separator) { printf(" %s %4.4x", name, val); show_mii_bits(val, decoder, prefix, separator); } static void show_mii_multibits(u16 *vals, const struct multi_bit_decoder *decoder, const char *prefix, const char *separator) { const char *strings[64]; multi_bit_decoder(strings, vals, decoder); print_strings(strings, prefix, separator); } static const char *protocol(unsigned int proto) { if (proto == 1) return "IEEE 802.3 CSMA/CD protocol"; else return "Using an unknown (non 802.3) encapsulation"; } static void show_protocol(unsigned int proto) { printf(" %s.\n", protocol(proto)); } /* AN advertisements etc */ // Clause 22 base page advert static const struct bit_decoder c22_base_advert[] = { { BIT(11), BIT(11), "AsymPause" }, { BIT(10), BIT(10), "Pause" }, { BIT(9), BIT(9), "100baseT4" }, { BIT(8), BIT(8), "100baseTx-FD" }, { BIT(7), BIT(7), "100baseTx" }, { BIT(6), BIT(6), "10baseT-FD" }, { BIT(5), BIT(5), "10baseT" }, { }, }; static void show_advert(u16 advert) { show_mii_reg("I'm advertising", advert, c22_base_advert, ".\n Advertising ", " "); printf(" Advertising %sadditional info pages.\n", advert & BIT(15) ? "" : "no "); show_protocol(advert & 31); } static void show_lpar(u16 lpar) { show_mii_reg("Link partner advertisment is", lpar, c22_base_advert, ".\n Advertising ", " "); if (lpar & BIT(13)) printf(" Remote fault.\n"); printf(" Negotiation %s.\n", lpar & BIT(14) ? "completed" : "did not complete"); } static void show_xnp(const char *prefix, u16 adv) { printf(" %s is %4.4x: ", prefix, adv); if (adv & BIT(13)) printf("message page %u\n", adv & 0x07ff); else printf("unformatted code %3.3x\n", adv & 0x07ff); } static void show_xnp_advert(u16 adv) { show_xnp("XNP advert", adv); } static void show_xnp_lpar(u16 lpa) { show_xnp("XNP link partner", lpa); } // Clause 28 base page and 1000Base-T control/status static void show_c28_advert(struct phy *phy, u16 *regs) { show_advert(regs[4]); if (regs[1] & BIT(8)) { printf(" 1000baseT control %4.4x:", regs[9]); if (regs[9] & BIT(8)) printf(" 1000baseT-HD"); if (regs[9] & BIT(9)) printf(" 1000baseT-FD"); printf("\n"); } } static void show_c28_lpar(struct phy *phy, u16 *regs) { show_lpar(regs[5]); if (regs[1] & BIT(8)) { printf(" 1000baseT status %4.4x:", regs[10]); if (regs[10] & BIT(10)) printf(" 1000baseT-HD"); if (regs[10] & BIT(11)) printf(" 1000baseT-FD"); if (regs[10] & BIT(12)) printf(" RemoteRxOK"); if (regs[10] & BIT(13)) printf(" LocalRxOK"); printf("\n"); } } static const struct c22_decoder c28_linkword = { .show_advert = show_c28_advert, .show_lpar = show_c28_lpar, }; // Clause 37 1000baseX advert static void show_c37_advert(struct phy *phy, u16 *regs) { u16 base = regs[4]; printf(" I'm advertising %4.4x:", base); if (base & BIT(6)) printf(" 1000baseX"); if (base & BIT(5)) printf(" 1000baseX-FD"); if (base & BIT(7)) printf(" Pause"); if (base & BIT(8)) printf(" AsymPause"); printf(".\n"); } static void show_c37_lpar(struct phy *phy, u16 *regs) { u16 base = regs[5]; if (base) { printf(" Link partner advertisment is %4.4x.\n Advertising", base); if (base & BIT(6)) printf(" 1000baseX"); if (base & BIT(5)) printf(" 1000baseX-FD"); if (base & BIT(7)) printf(" Pause"); if (base & BIT(8)) printf(" AsymPause"); printf(".\n"); } } static const struct c22_decoder c37_linkword = { .show_advert = show_c37_advert, .show_lpar = show_c37_lpar, }; // Cisco SGMII advert static const struct bit_decoder cisco_sgmii_adv_decoder[] = { { 0x8000, 0x0000, "Link Down" }, { 0x8000, 0x8000, "Link Up, " }, { 0x8c00, 0x8000, "10M" }, { 0x8c00, 0x8400, "100M" }, { 0x8c00, 0x8800, "1000M" }, { 0x8c00, 0x8c00, "?" }, { 0x9000, 0x8000, "/Half" }, { 0x9000, 0x9000, "/Full" }, { 0, 0, NULL }, }; static void cisco_sgmii_advert(struct phy *phy, u16 *regs) { const char *strings[17], **p = strings; u16 base = regs[4]; printf(" SGMII advertisement %4.4x", base); if (base & 1) p = bit_decoder(p, base, cisco_sgmii_adv_decoder); else *p++ = " Link down"; if (base & 0x63fe) *p++ = ", reserved bits are set"; *p = NULL; print_strings(strings, ": ", ""); } static void cisco_sgmii_lpar(struct phy *phy, u16 *regs) { u16 base = regs[5]; printf(" SGMII acknowledgement %4.4x: ", base); if (base & 1) printf("%s.", base == 0x4001 ? "MAC acknowledged" : "unknown"); else if (base == 0) printf("Unacknowledged."); printf("\n"); } static const struct c22_decoder cisco_sgmii_linkword = { .show_advert = cisco_sgmii_advert, .show_lpar = cisco_sgmii_lpar, }; // Clause 73.6 (baseR) advert static const struct bit_decoder c73_linkword_high16[] = { { BIT(15), BIT(15), "FEC requested" }, /* F1 */ { BIT(14), BIT(14), "FEC ability" }, /* F0 */ { }, }; static const struct bit_decoder c73_linkword_mid16[] = { { BIT(13), BIT(13), "100GbaseCR4" }, /* A8 */ { BIT(12), BIT(12), "100GbaseKR4" }, /* A7 */ { BIT(11), BIT(11), "100GbaseKP4" }, /* A6 */ { BIT(10), BIT(10), "100GbaseCR10" }, /* A5 */ { BIT(9), BIT(9), "40GbaseCR4" }, /* A4 */ { BIT(8), BIT(8), "40GbaseKR4" }, /* A3 */ { BIT(7), BIT(7), "10GbaseKR" }, /* A2 */ { BIT(6), BIT(6), "10GbaseKX4" }, /* A1 */ { BIT(5), BIT(5), "1000baseKX" }, /* A0 */ { }, }; static const struct bit_decoder c73_linkword_low16[] = { { BIT(11), BIT(11), "AsmPause" }, /* C1 */ { BIT(10), BIT(10), "Pause" }, /* C0 */ { }, }; static const struct multi_bit_decoder c73_linkword[] = { { 2, c73_linkword_high16 }, /* D32:D47 */ { 1, c73_linkword_mid16 }, /* D16:D31 */ { 0, c73_linkword_low16 }, /* D0:D15 */ { }, }; static void show_c73_linkword(const char *desc, u16 *lwp) { printf(" %s %4.4x%4.4x%4.4x.\n", desc, lwp[2], lwp[1], lwp[0]); show_mii_multibits(lwp, c73_linkword, " Advertising ", " "); if (lwp[0] & BIT(13)) printf(" Remote fault.\n"); show_protocol(lwp[0] & 31); } /* PMA/PMD tables */ // 1.0.5:2: Control register 1: Speed selection static const char *pma_speed[16] = { [0x0] = "10Gb/s", [0x1] = "10PASS-TS/2base-TL", [0x2] = "40Gb/s", [0x3] = "100Gb/s", [0x4] = "25Gb/s", [0x6] = "2.5Gb/s", // 802.3bz [0x7] = "5Gb/s", // 802.3bz }; // 1.4: PMA/PMD speed ability static const struct bit_decoder mii_c45_spd_cap_pma[] = { { BIT(8), BIT(8), "100G" }, { BIT(7), BIT(7), "40G" }, { BIT(0), BIT(0), "10G" }, { BIT(6), BIT(6), "10G/1G" }, { BIT(14), BIT(14), "5G" }, // 802.3bz { BIT(13), BIT(13), "2.5G" }, // 802.3bz { BIT(3), BIT(3), "1G" }, { BIT(4), BIT(4), "100M" }, { BIT(5), BIT(5), "10M" }, { BIT(2), BIT(2), "10PASS-TS" }, { BIT(1), BIT(1), "2base-TL" }, { }, }; // 1.7: PMA/PMD control 2 register static const char *mii_c45_type_pma[128] = { [0x00] = "10GbaseCX4", [0x01] = "10GbaseEW", [0x02] = "10GbaseLW", [0x03] = "10GbaseSW", [0x04] = "10GbaseLX4", [0x05] = "10GbaseER", [0x06] = "10GbaseLR", [0x07] = "10GbaseSR", [0x08] = "10GbaseLRM", [0x09] = "10GbaseT", [0x0a] = "10GbaseKX4", [0x0b] = "10GbaseKR", [0x0c] = "1000baseT", [0x0d] = "1000baseKX", [0x0e] = "100baseTX", [0x0f] = "10baseT", [0x10] = "10/1GbasePRX-D1", [0x11] = "10/1GbasePRX-D2", [0x12] = "10/1GbasePRX-D3", [0x13] = "10GbasePR-D1", [0x14] = "10GbasePR-D2", [0x15] = "10GbasePR-D3", [0x16] = "10/1GbasePRX-U1", [0x17] = "10/1GbasePRX-U2", [0x18] = "10/1GbasePRX-U3", [0x19] = "10GbasePR-U1", [0x1a] = "10GbasePR-U3", [0x26] = "40GbaseT", // 802.3bq [0x30] = "2.5GbaseT", [0x31] = "5GbaseT", // 802.3bz [0x37] = "25GbaseT", // 802.3bq [0x40] = "40GbaseKR4", [0x41] = "40GbaseCR4", [0x42] = "40GbaseSR4", [0x43] = "40GbaseLR4", [0x44] = "40GbaseFR", [0x50] = "100GbaseCR10", [0x51] = "100GbaseSR10", [0x52] = "100GbaseLR4", [0x53] = "100GbaseER4", }; // 1.8: PMA/PMD status 2 register static const struct bit_decoder mii_c45_stat_2_pma[] = { { BIT(0), BIT(0), "Local loopback" }, { BIT(1), BIT(1), "10GbaseEW" }, { BIT(2), BIT(2), "10GbaseLW" }, { BIT(3), BIT(3), "10GbaseSW" }, { BIT(4), BIT(4), "10GbaseLX4" }, { BIT(5), BIT(5), "10GbaseER" }, { BIT(6), BIT(6), "10GbaseLR" }, { BIT(7), BIT(7), "10GbaseSR" }, { BIT(8), BIT(8), "Transmit disable" }, { BIT(12), BIT(12), "Receive fault" }, { BIT(13), BIT(13), "Transmit fault" }, { }, }; // 1.11: PMA/PMD extended ability register static const struct bit_decoder mii_c45_ext_ability_pma[] = { { BIT(10), BIT(10), "40G/100G (below)" }, { BIT(0), BIT(0), "10GbaseCX4" }, { BIT(1), BIT(1), "10GbaseLRM" }, { BIT(2), BIT(2), "10GbaseT" }, { BIT(3), BIT(3), "10GbaseKX4" }, { BIT(4), BIT(4), "10GbaseKR" }, { BIT(14), BIT(14), "2.5G/5G (below)" }, // 802.3bz { BIT(5), BIT(5), "1000baseT" }, { BIT(6), BIT(6), "1000baseKX" }, { BIT(7), BIT(7), "100baseTX" }, { BIT(8), BIT(8), "10baseT" }, { BIT(9), BIT(9), "P2MP" }, { }, }; // 1.13: 40G/100G PMA/PMD extended ability register static const struct bit_decoder mii_c45_40g_ext_abl_pma[] = { { BIT(7), BIT(7), "100GbaseSR4" }, { BIT(8), BIT(8), "100GbaseCR10" }, { BIT(9), BIT(9), "100GbaseSR10" }, { BIT(10), BIT(10), "100GbaseLR4" }, { BIT(11), BIT(11), "100GbaseER4" }, { BIT(12), BIT(12), "100GbaseKP4" }, { BIT(13), BIT(13), "100GbaseKR4" }, { BIT(14), BIT(14), "100GbaseCR4" }, { BIT(0), BIT(0), "40GbaseKR4" }, { BIT(1), BIT(1), "40GbaseCR4" }, { BIT(2), BIT(2), "40GbaseSR4" }, { BIT(3), BIT(3), "40GbaseLR4" }, { BIT(4), BIT(4), "40GbaseFR" }, { BIT(5), BIT(5), "40GbaseER4" }, { BIT(6), BIT(6), "40GbaseT" }, // 802.3bq { BIT(15), BIT(15), "PMA remote loopback" }, { }, }; // 1.16: EEE capability static const struct bit_decoder mii_c45_eee_capability_pma[] = { { BIT(11), BIT(11), "100GBASE-CR4" }, { BIT(10), BIT(10), "100GBASE-KR4" }, { BIT(9), BIT(9), "100GBASE-KP4" }, { BIT(8), BIT(8), "100GBASE-CR10" }, { BIT(1), BIT(1), "40GBASE-CR4" }, { BIT(0), BIT(0), "40GBASE-KR4" }, { }, }; // 1.19: 25G PMA/PMD extended ability register static const struct bit_decoder mii_c45_25g_ext_abl_pma[] = { { BIT(5), BIT(5), "25GbaseT" }, // 802.3bq { }, }; // 1.21: 2.5G/5G PMA/PMD extended ability register static const struct bit_decoder mii_c45_nbase_ext_abl_pma[] = { { BIT(1), BIT(1), "5GbaseT" }, // 802.3bz { BIT(0), BIT(0), "2.5GbaseT" }, // 802.3bz { }, }; /* PCS */ // 3.0.5:2: Control register 1: Speed selection static const char *pcs_speed[16] = { [0x0] = "10Gb/s", [0x1] = "10PASS-TS/2base-TL", [0x2] = "10/1Gb/s", [0x3] = "40Gb/s", [0x4] = "100Gb/s", [0x7] = "2.5Gb/s", // 802.3bz [0x8] = "5Gb/s", // 802.3bz }; // 3.1: PCS status 1 register static const struct bit_decoder mii_c45_pcs_stat[] = { { BIT(11), BIT(11), "Tx LPI received" }, { BIT(10), BIT(10), "Rx LPI received" }, { BIT(9), BIT(9), "Tx LPI indication" }, { BIT(8), BIT(8), "Rx LPI indication" }, { BIT(6), BIT(6), "Clock stop capable" }, { BIT(1), BIT(1), "Supports low-power mode" }, { }, }; // 3.4: PCS speed ability register static const struct bit_decoder mii_c45_spd_cap_pcs[] = { { BIT(3), BIT(3), "100G" }, { BIT(2), BIT(2), "40G" }, { BIT(0), BIT(0), "10G" }, { BIT(7), BIT(7), "5G" }, // 802.3bz { BIT(6), BIT(6), "2.5G" }, // 802.3bz { BIT(1), BIT(1), "10PASS-TS/2base-TL" }, { }, }; // 3.7.3:0 PCS type selection static const char *mii_c45_type_pcs[16] = { [0x0] = "10GbaseR", [0x1] = "10GbaseX", [0x2] = "10GbaseW", [0x3] = "10GbaseT", [0x4] = "40GbaseR", [0x5] = "100GbaseR", [0x6] = "40GbaseT", // 802.3bq [0x7] = "25GbaseR", // 802.3bq [0x9] = "25GbaseT", // 802.3bq [0xa] = "2.5GbaseT", // 802.3bz [0xb] = "5GbaseT", // 802.3bz }; // 3.8: PCS status 2 register static const struct bit_decoder mii_c45_stat_2_pcs[] = { { BIT(5), BIT(5), "100GbaseR" }, { BIT(4), BIT(4), "40GbaseR" }, { BIT(6), BIT(6), "40GbaseT" }, // 802.3bq { BIT(9), BIT(9), "25GbaseT" }, // 802.3bq { BIT(0), BIT(0), "10GbaseR" }, { BIT(1), BIT(1), "10GbaseX" }, { BIT(2), BIT(2), "10GbaseW" }, { BIT(3), BIT(3), "10GbaseT" }, { BIT(12), BIT(12), "5GbaseT" }, // 802.3bz { BIT(13), BIT(13), "2.5GbaseT" }, // 802.3bz { }, }; // 3.20: EEE control and capability static const struct bit_decoder mii_c45_eee_ctrl_capab_pcs[] = { { BIT(13), BIT(13), "100GBASE-R deep sleep" }, { BIT(12), BIT(12), "100GBASE-R fast wake" }, { BIT(9), BIT(9), "40GBASE-R deep sleep" }, { BIT(8), BIT(8), "40GBASE-R fast wake" }, { BIT(6), BIT(6), "10GBASE-KR" }, { BIT(5), BIT(5), "10GBASE-KX4" }, { BIT(4), BIT(4), "1000BASE-KX" }, { BIT(3), BIT(3), "10GBASE-T" }, { BIT(2), BIT(2), "1000BASE-T" }, { BIT(1), BIT(1), "100BASE-TX" }, { BIT(0), BIT(0), "FastWake" }, { }, }; // 3.32: baseR and MultiGbaseT PCS status 1 register static const struct bit_decoder mii_pcs_basert_stat1[] = { { BIT(12), BIT(12), "PCS receive link up" }, { BIT(3), BIT(3), "PRBS9 pattern testing" }, { BIT(2), BIT(2), "PRBS31 pattern testing" }, { BIT(1), BIT(1), "High BER" }, { BIT(0), BIT(0), "Block lock" }, { }, }; // 3.33: baseR and MultiGbaseT PCS status 2 register static const struct bit_decoder mii_pcs_basert_stat2[] = { { BIT(15), BIT(15), "Block lock (latched)" }, { BIT(14), BIT(14), "High BER (latched)" }, { }, }; static const struct multi_bit_decoder mii_pcs_basert_stat[] = { { MMD_PCS_BASERT_STAT1, mii_pcs_basert_stat1 }, { MMD_PCS_BASERT_STAT2, mii_pcs_basert_stat2 }, { }, }; /* PHY XGXS / DTE XGXS */ // 4.0.5:2: PHY XGXS Control register 1: Speed selection // 5.0.5:2: DTE XGXS Control register 1: Speed selection static const char *xs_speed[16] = { [0x0] = "10Gb/s", }; // 4.1: PHYXS status 1 register static const struct bit_decoder mii_c45_phyxs_stat[] = { { BIT(11), BIT(11), "Tx LPI received" }, { BIT(10), BIT(10), "Rx LPI received" }, { BIT(9), BIT(9), "Tx LPI indication" }, { BIT(8), BIT(8), "Rx LPI indication" }, { BIT(6), BIT(6), "Clock stop capable" }, { BIT(1), BIT(1), "Supports low-power mode" }, { }, }; // 4.4: PHY XGXS speed ability register // 5.4: DTE XGXS speed ability register static const struct bit_decoder mii_c45_spd_cap_xs[] = { { BIT(0), BIT(0), "10G" }, { }, }; // 4.20: EEE capability // 5.20: EEE capability static const struct bit_decoder mii_c45_eee_ctrl_capab_xs[] = { { BIT(4), BIT(4), "EEE" }, { BIT(0), BIT(0), "XAUI stop capable" }, { }, }; // 4.24: PHY XGXS lane status register static const struct bit_decoder mii_phyxs_lane_status[] = { { BIT(12), BIT(12), "lanes synchronized and aligned" }, { BIT(11), BIT(11), "pattern testing supported" }, { BIT(10), BIT(10), "loopback support" }, { BIT(3), BIT(3), "lane 3 synchronized" }, { BIT(2), BIT(2), "lane 2 synchronized" }, { BIT(1), BIT(1), "lane 2 synchronized" }, { BIT(0), BIT(0), "lane 2 synchronized" }, { }, }; /* AN */ // 7.1: AN status static const struct bit_decoder mii_c45_an_stat[] = { { BIT(3), 0, "Unable to perform Auto-negotiation.\n" }, { BIT(3) | BIT(5), BIT(3), "Able to perform Auto-negotiation, negotiation not complete.\n" }, { BIT(3) | BIT(5), BIT(3) | BIT(5), "Able to perform Auto-negotiation, negotiation complete.\n" }, { BIT(0), BIT(0), "LP Auto-negotiation" }, { BIT(4), BIT(4), "Remote fault" }, { BIT(6), BIT(6), "Page Rcvd" }, { BIT(7), BIT(7), "Ext Next Pg" }, { BIT(9), BIT(9), "Parallel detection fault" }, { }, }; // 7.32: 10GbaseT AN control register (tech bits) static const struct bit_decoder mii_c45_an_multi_gbt_tech[] = { /* 0..2 below */ { BIT(3), BIT(3), "40GbaseT/fast" }, // 802.3bq { BIT(11), BIT(11), "40GbaseT" }, // 802.3bq { BIT(9), BIT(9), "25GbaseT/fast" }, // 802.3bq { BIT(10), BIT(10), "25GbaseT" }, // 802.3bq { BIT(12), BIT(12), "10GbaseT" }, { BIT(6), BIT(6), "5GbaseT/fast" }, // 802.3bz { BIT(8), BIT(8), "5GbaseT" }, // 802.3bz { BIT(5), BIT(5), "2.5GbaseT/fast" }, // 802.3bz { BIT(7), BIT(7), "2.5GbaseT" }, // 802.3bz /* 13..15 below */ { }, }; // 7.32: 10GbaseT AN control register (other bits) static const struct bit_decoder mii_c45_an_multi_gbt_other[] = { { 0, 0, "\n" }, { BIT(15) | BIT(14), BIT(15), "I'm configured to be the slave phy.\n" }, { BIT(15) | BIT(14), BIT(15) | BIT(14), "I'm configured to be the master phy.\n" }, { BIT(13), BIT(13), "I'm part of a multi-port device.\n" }, { BIT(13), 0, "I'm part of a single-port device.\n" }, { BIT(2), BIT(2), "10GbaseT LD frame reset" }, { BIT(1), BIT(1), "10GbaseT Fast retrain" }, { BIT(0), BIT(0), "10GbaseT LD loop timing" }, { }, }; static const struct multi_bit_decoder mii_c45_an_advert[] = { { MMD_AN_MULTI_GBT_CTRL, mii_c45_an_multi_gbt_tech }, { MMD_AN_BASE_ADV0, c22_base_advert }, { MMD_AN_MULTI_GBT_CTRL, mii_c45_an_multi_gbt_other }, { }, }; // 7.33: 10GbaseT AN status register static const struct bit_decoder mii_an_multi_gbt_stat[] = { { BIT(15), BIT(15), "Master/slave config fault" }, { BIT(14), BIT(14), "Local PHY master" }, { BIT(14), 0 << 14, "Local PHY slave" }, { BIT(13), 0 << 13, "Local RX not ok" }, { BIT(12), 0 << 13, "Remote RX not ok" }, { BIT(10), BIT(10), "LP loop timing" }, { BIT(8), BIT(8), "LP 40GbaseT" }, // 802.3bq { BIT(2), BIT(2), "LP 25GbaseT/fast" }, // 802.3bq { BIT(7), BIT(7), "LP 25GbaseT" }, // 802.3bq { BIT(9), BIT(9), "LP 10GbaseT PMA retrain req" }, // 802.3bq { BIT(11), BIT(11), "LP 10GbaseT" }, { BIT(4), BIT(4), "LP 5GbaseT/fast" }, // 802.3bz { BIT(6), BIT(6), "LP 5GbaseT" }, // 802.3bz { BIT(3), BIT(3), "LP 2.5GbaseT/fast" }, // 802.3bz { BIT(5), BIT(5), "LP 2.5GbaseT" }, // 802.3bz { BIT(1), BIT(1), "LP Fast retrain" }, { } }; // 7.48: Backplane Ethernet, baseR copper status #define BASE_R_PORT_TYPE_MASK 0x0f6e static const struct bit_decoder mii_an_baser_status[] = { { BASE_R_PORT_TYPE_MASK, BIT(1), "1000baseKX" }, { BASE_R_PORT_TYPE_MASK, BIT(2), "10GbaseKX4 or CX4" }, { BASE_R_PORT_TYPE_MASK, BIT(3), "10GbaseKR" }, { BASE_R_PORT_TYPE_MASK, BIT(5), "40GbaseKR4" }, { BASE_R_PORT_TYPE_MASK, BIT(6), "40GbaseCR4" }, { BASE_R_PORT_TYPE_MASK, BIT(8), "100GbaseCR10" }, { BASE_R_PORT_TYPE_MASK, BIT(9), "100GbaseKP4" }, { BASE_R_PORT_TYPE_MASK, BIT(10), "100GbaseKR4" }, { BASE_R_PORT_TYPE_MASK, BIT(11), "100GbaseCR4" }, { BIT(4), BIT(4), "FEC" }, { } }; // 7.60: EEE advertisement // 7.61: EEE link partner ability static const struct bit_decoder mii_an_eee_advertisement[] = { { BIT(13), BIT(13), "100GBASE-CR4" }, { BIT(12), BIT(12), "100GBASE-KR4" }, { BIT(11), BIT(11), "100GBASE-KP4" }, { BIT(10), BIT(10), "100GBASE-CR10" }, { BIT(8), BIT(8), "40GBASE-CR4" }, { BIT(7), BIT(7), "40GBASE-KR4" }, { BIT(6), BIT(6), "10GBASE-KR" }, { BIT(5), BIT(5), "10GBASE-KX4" }, { BIT(4), BIT(4), "1000BASE-KX" }, { BIT(3), BIT(3), "10GBASE-T" }, { BIT(2), BIT(2), "1000BASE-T" }, { BIT(1), BIT(1), "100BASE-TX" }, { } }; static const char *mii_c45_speed(int devad) { const char **speed_table = NULL; unsigned int speed; switch (devad) { case MDIO_MMD_PMAPMD: speed_table = pma_speed; break; case MDIO_MMD_PCS: speed_table = pcs_speed; break; case MDIO_MMD_PHY_XS: case MDIO_MMD_DTE_XS: speed_table = xs_speed; break; } switch (mii_val[MMD_CTRL1] & 0x2040) { case 0x0000: return "10Mb/s"; case 0x0040: return "100Mb/s"; case 0x2000: return "1Gb/s"; case 0x2040: speed = (mii_val[MMD_CTRL1] & 0x003c) >> 2; if (speed_table && speed_table[speed]) return speed_table[speed]; default: return "Reserved"; } } static void show_mii_c45_status2(const struct phy *phy, u16 stat2, const struct bit_decoder *decoder) { u16 new_stat2 = mdio_read_phy(phy, MMD_STAT2); printf(" Status 2 register %4.4x ... %4.4x\n", stat2, new_stat2); if (decoder) show_mii_bits(stat2, decoder, " Abilities: ", ", "); if (new_stat2 & BIT(11)) printf(" *Transmit fault reported*.\n"); else if (stat2 & BIT(11)) printf(" Transmit fault previously reported, but now cleared.\n"); if (new_stat2 & BIT(10)) printf(" *Receive fault reported*.\n"); else if (stat2 & BIT(10)) printf(" Receive fault previously reported, but now cleared.\n"); } static void show_mii_c45_pmapmd_10gbt_status(const struct phy *phy) { static const char *mdi[4] = { "AB and CD crossed", "Reserved", "Reserved", "no crossover" }; u16 rval[18]; int val, i; for (i = 0; i < sizeof(rval) / 2; i++) { val = mdio_read_phy(phy, MMD_PMA_10GBT_SWAPPOL + i); rval[i] = val < 0 ? 0 : val; } printf(" Pair swap %4.4x: MDI %s, A %s, B %s, C %s, D %s.\n", rval[0], mdi[rval[0] & 3], rval[0] & BIT(8) ? "reversed" : "normal", rval[0] & BIT(9) ? "reversed" : "normal", rval[0] & BIT(10) ? "reversed" : "normal", rval[0] & BIT(11) ? "reversed" : "normal"); if (rval[1]) printf(" TX backoff %4.4x: LP TX backoff %udB TX backoff %udB%s.\n", rval[1], 2 * ((rval[1] & 0xe000) >> 13), 2 * ((rval[1] & 0x1c00) >> 10), rval[1] & 1 ? " short reach" : ""); #define SNR(x) (((x) - 0x8000) / 10.f) printf(" Operating SNR: A: %5.1fdB B: %5.1fdB C: %5.1fdB D: %5.1fdB.\n", SNR(rval[3]), SNR(rval[4]), SNR(rval[5]), SNR(rval[6])); printf(" Minimum SNR : A: %5.1fdB B: %5.1fdB C: %5.1fdB D: %5.1fdB.\n", SNR(rval[7]), SNR(rval[8]), SNR(rval[9]), SNR(rval[10])); if (rval[11] || rval[12] || rval[13] || rval[14]) printf(" RX power : A: %5.1fdBm B: %5.1fdBm C: %5.1fdBm D: %5.1fdBm.\n", SNR(rval[11]), SNR(rval[12]), SNR(rval[13]), SNR(rval[14])); #define SKEW(x) (((int)((x) & 0x7f) - 64) * 1.25f) printf(" Skew A>B %6.2fns A>C %6.2fns A>D %6.2fns\n", SKEW(rval[15] >> 8), SKEW(rval[16]), SKEW(rval[16] >> 8)); if (rval[17]) printf(" Fast retrain %4.4x.\n", rval[17]); } static const char *c45_mmd_name(unsigned int devad) { const char *name = mmd_name[devad]; return name ? name : ""; } static void show_mii_c45_details(const struct phy *phy) { const struct bit_decoder *decoder; const char *type; const char *col_end = "\033[m"; const char *col_red = "\033[31m"; const char *col_grn = "\033[32m"; int new_stat, val; if (mii_val[MMD_CTRL1] == 0xffff) { printf(" No MII transceiver present!.\n"); return; } if (phy->devad == MDIO_MMD_VENDOR1 || phy->devad == MDIO_MMD_VENDOR2) return; if ((mii_val[MMD_STAT2] & 0xc000) != 0x8000 && (phy->phy_id & 0xc000) != 0xc000 && phy->devad != MDIO_MMD_AN) { printf(" No device responding at this address!\n"); return; } printf(" Control 1 register %4.4x: ", mii_val[MMD_CTRL1]); switch (phy->devad) { case MDIO_MMD_PMAPMD: if (c45_an_ctrl & BIT(12)) { printf("Speed determined by auto-negotiation.\n"); break; } /*FALLTHROUGH*/ default: printf("Speed %s.\n", mii_c45_speed(phy->devad)); break; case MDIO_MMD_AN: printf("Auto-negotiation %sabled.\n", mii_val[MMD_CTRL1] & BIT(12) ? "en" : "dis"); break; } new_stat = mdio_read_phy(phy, MMD_STAT1); printf(" Status register %4.4x ... %4.4x.\n", mii_val[MMD_STAT1], new_stat); switch (phy->devad) { case MDIO_MMD_PMAPMD: /* has fault */ case MDIO_MMD_PCS: /* has fault */ case MDIO_MMD_DTE_XS: /* has fault */ type = "Receive link"; break; case MDIO_MMD_PHY_XS: /* has fault */ type = "Transmit link"; break; case MDIO_MMD_WIS: /* no fault */ case MDIO_MMD_AN: /* no fault */ default: type = NULL; break; } if (!type) { printf(" Link status: %s%sestablished%s.\n", /* transmit on #4 */ new_stat & BIT(2) ? col_grn : col_red, mii_val[MMD_STAT1] & BIT(2) ? "" : new_stat & BIT(2) ? "previously broken, but now re" : "not ", col_end); } else { printf(" %s status: %s%sestablished%s.%s\n", type, /* transmit on #4 */ new_stat & BIT(2) ? col_grn : col_red, mii_val[MMD_STAT1] & BIT(2) ? "" : new_stat & BIT(2) ? "previously broken, but now re" : "not ", col_end, new_stat & BIT(7) ? "\n *Fault condition detected*" : mii_val[MMD_STAT1] & BIT(7) ? "\n Fault condition previously reported, but now cleared" : ""); } switch (phy->devad) { case MDIO_MMD_PCS: decoder = mii_c45_pcs_stat; break; case MDIO_MMD_PHY_XS: decoder = mii_c45_phyxs_stat; break; case MDIO_MMD_AN: decoder = mii_c45_an_stat; break; default: decoder = NULL; break; } if (decoder) show_mii_bits(new_stat, decoder, " ", ", "); switch (phy->devad) { case MDIO_MMD_PMAPMD: decoder = mii_c45_spd_cap_pma; type = mii_c45_type_pma[mii_val[MMD_CTRL2] & 0x007f]; if (c45_an_ctrl & BIT(12)) type = "determined by auto-negotiation"; break; case MDIO_MMD_PCS: decoder = mii_c45_spd_cap_pcs; type = mii_c45_type_pcs[mii_val[MMD_CTRL2] & 0x000f]; break; case MDIO_MMD_PHY_XS: case MDIO_MMD_DTE_XS: decoder = mii_c45_spd_cap_xs; type = NULL; break; default: decoder = NULL; type = NULL; break; } if (decoder) show_mii_reg("Speed capability", mii_val[MMD_SPEED], decoder, ": ", ", "); if (phy->devad == MDIO_MMD_PMAPMD || phy->devad == MDIO_MMD_PCS) { if (!type) type = "unknown"; printf(" Control 2 register %4.4x: Type %s.\n", mii_val[MMD_CTRL2], type); } switch (phy->devad) { case MDIO_MMD_PMAPMD: show_mii_c45_status2(phy, mii_val[MMD_STAT2], mii_c45_stat_2_pma); if (mii_val[MMD_PMA_EXT_ABL]) show_mii_reg("Extended Ability register", mii_val[MMD_PMA_EXT_ABL], mii_c45_ext_ability_pma, "\n Abilities: ", ", "); // Don't have the information for this yet... if (mii_val[MMD_PMA_25G_EXT_ABL]) show_mii_reg("25G Extended Ability register", mii_val[MMD_PMA_25G_EXT_ABL], mii_c45_25g_ext_abl_pma, "\n Abilities: ", ", "); if (mii_val[MMD_PMA_EXT_ABL] & BIT(10)) show_mii_reg("40G/100G Extended Ability register", mii_val[MMD_PMA_40G100G_EXT_ABL], mii_c45_40g_ext_abl_pma, "\n Abilities: ", ", "); // This should be predicated on a bit in MMD_PMA_EXT_ABL // but 88x3310 doesn't do this! if (mii_val[MMD_PMA_NBASE_EXT_ABL]) show_mii_reg("2.5G/5G Extended Ability register", mii_val[MMD_PMA_NBASE_EXT_ABL], mii_c45_nbase_ext_abl_pma, "\n Abilities: ", ", "); val = mdio_read_phy(phy, MMD_PMA_10GBT_STATUS); if (val & 1) show_mii_c45_pmapmd_10gbt_status(phy); if (mii_val[MMD_PMA_EEE_CAPABILITY]) show_mii_reg("EEE capabilities", mii_val[MMD_PMA_EEE_CAPABILITY], mii_c45_eee_capability_pma, "\n ", ", "); break; case MDIO_MMD_PCS: show_mii_c45_status2(phy, mii_val[MMD_STAT2], mii_c45_stat_2_pcs); printf(" baseR or 10GbaseT status %4.4x %4.4x", mii_val[MMD_PCS_BASERT_STAT1], mii_val[MMD_PCS_BASERT_STAT2]); show_mii_multibits(mii_val, mii_pcs_basert_stat, "\n ", "\n "); if (mii_val[MMD_PCS_EEE_CTRL_CAPAB]) { show_mii_reg("EEE control and capabilities", mii_val[MMD_PCS_EEE_CTRL_CAPAB], mii_c45_eee_ctrl_capab_pcs, "\n ", ", "); printf(" EEE wake error counter: %4.4x\n", mii_val[MMD_PCS_EEE_WAKE_ERR]); } break; case MDIO_MMD_PHY_XS: if (mii_val[MMD_PHY_XS_EEE_CAPAB]) { show_mii_reg("EEE capabilities", mii_val[MMD_PHY_XS_EEE_CAPAB], mii_c45_eee_ctrl_capab_xs, "\n ", ", "); printf(" EEE wake error counter: %4.4x\n", mii_val[MMD_PHY_XS_EEE_WAKE_ERR]); } val = mii_val[MMD_PHY_XS_LANE_STATUS]; show_mii_reg("Lane Status", val, mii_phyxs_lane_status, ":\n ", "\n "); break; case MDIO_MMD_DTE_XS: if (mii_val[MMD_DTE_XS_EEE_CAPAB]) { show_mii_reg("EEE capabilities", mii_val[MMD_DTE_XS_EEE_CAPAB], mii_c45_eee_ctrl_capab_xs, "\n ", ", "); printf(" EEE wake error counter: %4.4x\n", mii_val[MMD_DTE_XS_EEE_WAKE_ERR]); } break; case MDIO_MMD_AN: val = mdio_read_phy(phy, MMD_AN_BASER_STAT); if (val < 0) val = 0; if (val & 1) { /* bits defined as per 73.6. */ show_c73_linkword("I'm advertising", mii_val + MMD_AN_BASE_ADV0); if (mii_val[MMD_AN_BASE_LPA2] | mii_val[MMD_AN_BASE_LPA1] | mii_val[MMD_AN_BASE_LPA0]) show_c73_linkword("Link partner advertisment is", mii_val + MMD_AN_BASE_LPA0); show_mii_reg("baseR Status", val, mii_an_baser_status, ": ", " "); } else { /* bits defined as per 28.2.1.2. */ printf(" I'm advertising %4.4x %4.4x.\n", mii_val[MMD_AN_BASE_ADV0], mii_val[MMD_AN_MULTI_GBT_CTRL]); show_mii_multibits(mii_val, mii_c45_an_advert, " ", " "); printf(" Advertising %sadditional info pages.\n", mii_val[MMD_AN_BASE_ADV0] & BIT(15) ? "" : "no "); show_protocol(mii_val[MMD_AN_BASE_ADV0] & 31); show_lpar(mii_val[MMD_AN_BASE_LPA0]); } if (mii_val[MMD_AN_MULTI_GBT_CTRL]) show_mii_reg("10GbaseT status", mii_val[MMD_AN_MULTI_GBT_STAT], mii_an_multi_gbt_stat, "\n ", ", "); if (mii_val[MMD_CTRL1] & BIT(13)) { show_xnp_advert(mii_val[MMD_AN_XNP_ADV0]); show_xnp_lpar(mii_val[MMD_AN_XNP_LPA0]); } if (mii_val[MMD_AN_EEE_ADV]) { show_mii_reg("EEE advertisement", mii_val[MMD_AN_EEE_ADV], mii_an_eee_advertisement, "\n ", ", "); } if (mii_val[MMD_AN_EEE_LPA]) { show_mii_reg("EEE link partner advertisement", mii_val[MMD_AN_EEE_LPA], mii_an_eee_advertisement, "\n ", ", "); } break; } } static void show_mii_c22_details(struct phy *phy, const struct c22_decoder *dec) { const char *col_end = "\033[m"; const char *col_red = "\033[31m"; const char *col_grn = "\033[32m"; int i; u16 bmcr, bmsr, new_bmsr; if (mii_val[0] == 0xffff) { printf(" No MII transceiver present!.\n"); return; } bmcr = mii_val[0]; bmsr = mii_val[1]; printf(" Basic mode control register %4.4x:", bmcr); if (bmcr & BIT(12)) printf(" Auto-negotiation enabled.\n"); else printf(" Auto-negotiation disabled!\n" " Speed fixed at 10%s mbps, %s-duplex.\n", bmcr & BIT(6) ? "00" : bmcr & BIT(13) ? "0" : "", bmcr & BIT(8) ? "full":"half"); if (bmcr & BIT(15)) printf(" Transceiver currently being reset!\n"); if (bmcr & BIT(14)) printf(" Transceiver in loopback mode!\n"); if (bmcr & BIT(11)) printf(" Transceiver powered down!\n"); if (bmcr & BIT(10)) printf(" Transceiver isolated from the MII!\n"); if (bmcr & BIT(9)) printf(" Restarted auto-negotiation in progress!\n"); if (bmcr & BIT(7)) printf(" Internal Collision-Test enabled!\n"); new_bmsr = mdio_read_phy(phy, 1); printf(" Basic mode status register %4.4x ... %4.4x.\n", bmsr, new_bmsr); if (bmsr & BIT(8)) printf(" With extended status register %4.4x.\n", mii_val[15]); printf(" Link status: %s%sestablished%s.\n" " Capable of", new_bmsr & BIT(2) ? col_grn : col_red, bmsr & BIT(2) ? "" : (new_bmsr & BIT(2)) ? "previously broken, but now re" : "not ", col_end); if (bmsr & 0xF800 || (bmsr & BIT(8) && mii_val[15] & 0xf000)) { for (i = 15; i >= 11; i--) if (bmsr & (1<"); printf(".\n" " %s to perform Auto-negotiation, negotiation %scomplete.\n", bmsr & BIT(3) ? "Able" : "Unable", bmsr & BIT(5) ? "" : "not "); if (bmsr & BIT(4)) printf(" Remote fault detected!\n"); if (bmsr & BIT(1)) printf(" *** Link Jabber! ***\n"); dec->show_advert(phy, mii_val); dec->show_lpar(phy, mii_val); } static int show_c22_subdev(struct phy *phy, int subdev, unsigned int off, const struct c22_decoder *dec) { int vendor = 0; phy->offset = off; if (phy->phy_id & 0x8000) printf("\n MII PHY #%d:%d %s", (phy->phy_id >> 5) & 31, phy->devad, c45_mmd_name(phy->devad)); else printf("\n MII PHY #%d", phy->phy_id); if (subdev) printf(" Subdevice #%d", subdev); printf(" transceiver registers:"); read_mii_regs(phy->ioaddr, phy->phy_id | phy->devad, off, 32); show_mii_regs(32); printf(".\n"); if (mii_val[2] ^ mii_val[3]) { /* Eliminate 0x0000 and 0xffff IDs. */ vendor = lookup_vendor(mii_val[2], mii_val[3]); } else { printf(" This transceiver has no vendor identification.\n"); } show_mii_c22_details(phy, dec); return vendor; } static int show_c45_subdev(struct phy *phy, int subdev, unsigned int off) { const char *name = c45_mmd_name(phy->devad); int vendor = 0; phy->offset = off; if (subdev) printf("\n MII PHY #%d:%d %s Subdevice #%d transceiver registers:", (phy->phy_id >> 5) & 31, phy->devad, name, subdev); else printf("\n MII PHY #%d:%d %s transceiver registers:", (phy->phy_id >> 5) & 31, phy->devad, name); read_mii_regs(phy->ioaddr, phy->phy_id | phy->devad, off, 64); show_mii_regs(64); printf(".\n"); if (phy->devad != MDIO_MMD_VENDOR1 && phy->devad != MDIO_MMD_VENDOR2) { if (mii_val[MMD_DEVID1] ^ mii_val[MMD_DEVID2]) { vendor = lookup_vendor(mii_val[MMD_DEVID1], mii_val[MMD_DEVID2]); } else { printf(" This transceiver has no vendor identification.\n"); } } show_mii_c45_details(phy); return vendor; } void show_mii_details(long ioaddr, int phy_id) { DEFINE_C22_PHY(phy, ioaddr, phy_id); int vendor, i; /* This may not be omitted from the output. */ printf("%s", version_msg); if ((phy_id & 0x801f) == 0x8000) { int val; u32 v, mmds = 0; for (i = 1; i < 32; i++) { val = mdio_read(ioaddr, phy_id | i, MMD_DEVPKG1); if (val < 0) continue; v = val; val = mdio_read(ioaddr, phy_id | i, MMD_DEVPKG2); if (val < 0) continue; v |= val << 16; if (v == 0xffffffff) continue; mmds = v; break; } if (mmds & BIT(7)) { val = mdio_read(ioaddr, phy_id | MDIO_MMD_AN, MMD_CTRL1); if (val >= 0) c45_an_ctrl = val; } for (i = 1; i < 32; i++) { if (mmds & (1 << i)) { phy.devad = i; vendor = show_c45_subdev(&phy, 0, 0); if (oui_map[vendor].func) oui_map[vendor].func(ioaddr, phy_id | i); } } } else if (phy_id & 0x8000) { phy.devad = phy.phy_id & 31; phy.phy_id &= ~31; vendor = show_c45_subdev(&phy, 0, 0); if (oui_map[vendor].func) oui_map[vendor].func(ioaddr, phy_id); } else { vendor = show_c22_subdev(&phy, 0, 0, &c28_linkword); if (oui_map[vendor].func) oui_map[vendor].func(ioaddr, phy_id); } } static void dump_mii_range(long ioaddr, int phy_id, unsigned int start, unsigned int len) { unsigned int i, j; int gap = 0; for (i = start; i < start + len; i += 8) { u16 vals[8], v; for (j = 0, v = 0; j < 8; j++) { int val = mdio_read(ioaddr, phy_id, i + j); if (val < 0) val = 0; vals[j] = val; v |= val; } if (v) { if (gap) { printf("\n ..."); gap = 0; } printf("\n %4.4x:", i); for (j = 0; j < 8; j++) printf(" %4.4x", vals[j]); } else { gap = 1; } } printf("\n"); } void dump_mii(long ioaddr, int phy_id) { unsigned int max; if (phy_id & 0x8000) max = 65536; else max = 32; printf(" MII PHY #%d transceiver registers:", phy_id); dump_mii_range(ioaddr, phy_id, 0, max); } int monitor_mii(long ioaddr, int phy_id) { int i, last_event = 0; unsigned short new_1, baseline_1 = mdio_read(ioaddr, phy_id, 1); struct timeval tv, sleepval; time_t cur_time; char timebuf[12]; if (baseline_1 == 0xffff) { fprintf(stderr, "No MII transceiver present to monitor.\n"); return -1; } gettimeofday(&tv, NULL); cur_time = tv.tv_sec; strftime(timebuf, sizeof(timebuf), "%H:%M:%S", localtime(&cur_time)); printf("Monitoring the MII transceiver status.\n" "%s.%03d Baseline value of MII BMSR (basic mode status register)" " is %4.4x.\n", timebuf, (int)tv.tv_usec/1000, baseline_1); while (1) { new_1 = mdio_read(ioaddr, phy_id, 1); if (new_1 == 0xffff) { fprintf(stderr, "The MII transceiver is no longer accessable!\n"); return -1; } if (new_1 != baseline_1) { gettimeofday(&tv, NULL); cur_time = tv.tv_sec; strftime(timebuf, sizeof(timebuf), "%H:%M:%S", localtime(&cur_time)); printf("%s.%03d MII BMSR now %4.4x: %4s link, NWay %s, " "%3sJabber%s (%4.4x).\n", timebuf, (int)tv.tv_usec/1000, new_1, new_1 & 0x04 ? "Good" : "no", new_1 & 0x20 ? "done" : "busy", new_1 & 0x02 ? "" : "No ", new_1 & 0x10 ? ", remote fault" : "", mdio_read(ioaddr, phy_id, 5) ); if (!(baseline_1 & 0x20) && (new_1 & 0x20)) { int lkpar = mdio_read(ioaddr, phy_id, 5); printf(" New link partner capability is %4.4x %4.4x:", lkpar, mdio_read(ioaddr, phy_id, 6)); switch (lkpar) { case 0x45e1: printf(" 10/100 switch w/ flow control"); break; case 0x41e1: printf(" 10/100 HD+FD switch"); break; case 0x40a1: printf(" 10/100 bridged repeater"); break; case 0x4081: printf(" 100baseTx repeater w/autonegotation"); break; case 0x0081: printf(" 100baseTx (no autonegotation)"); break; case 0x4021: printf(" 10baseT repeater w/autonegotation"); break; case 0x0021: printf(" 10baseT (no autonegotation)"); break; default: for (i = 9; i >= 5; i--) if (lkpar & (1< 30 ? 200000 : 1000; select(0, 0, 0, 0, &sleepval); /* Or just sleep(1); */ } printf(" Value of MII BMSR (basic mode status register) is %4.4x.\n", mdio_read(ioaddr, phy_id, 1)); return 0; } /* Emit transceiver-specific info. */ static void qs6612(long ioaddr, int phy_id) { printf(" QS6612 extra registers: Mode %4.4x.\n" " Interrupt source %4.4x, mask %4.4x.\n" " PHY control %4.4x.\n", mii_val[17], mii_val[29], mii_val[30], mii_val[31]); return; } static void ns83843(long ioaddr, int phy_id) { printf(" NatSemi 83843 extra registers:\n" " PHY status %4.4x\n" " %s link, %d Mb/sec %s duplex\n" " MII interrupts %sabled, %s pending.\n" " Events since last read\n" " Link disconnects %d\n" " False carriers %d\n" " Receive errors %d\n" " Link beat is currently %sstable\n", mii_val[0x10], mii_val[10] & BIT(0) ? "Valid" : "Invalid", mii_val[10] & BIT(1) ? 10 : 100, mii_val[10] & BIT(2) ? "full" : "half", mii_val[0x11] & BIT(1) ? "en":"dis", mii_val[0x10] & BIT(8) ? "interrupt": "none", mii_val[0x13], mii_val[0x14], mii_val[0x15], mii_val[0x16] & BIT(4) ? "UN" : ""); return; } static void smsc83c180(long ioaddr, int phy_id) { int mii_reg25 = mii_val[25]; printf(" SMSC 83c180 extra registers:\n" " Auto-negotiation status 0x%4.4x.\n" " 10baseT polarity is %s.\n" " PHY address is %d.\n" " Auto-negotiation %scomplete, 1%s0Mbps %s duplex.\n" " Rx symbol errors since last read %d.\n", mii_reg25, mii_reg25 & BIT(13) ? "normal" : "reversed", (mii_reg25>>8) & 0x1F, mii_reg25 & BIT(7) ? "did not " : "", mii_reg25 & BIT(5) ? "0" : "", mii_reg25 & BIT(6) ? "full" : "half", mdio_read(ioaddr, phy_id, 26)); return; } static const char *tdk_events[8] = { "Jabber", "Rx error", "Negotiation page received", "Link detection fault", "Link partner acknowledge", "Link status change", "Remote partner fault", "Auto-Negotiation complete"}; static const struct msg_tbl tdk_reg16[] = { {0x8000, " Transceiver is in repeater mode!"}, {0x4000, " Interrupt pin set to active high."}, {0x2000, " Reserved bit 12 is unexpectedly set."}, {0x1000, " Transmit pins are internally disconnected."}, {0x0800, " 10baseT signal quality test is disabled."}, {0x0400, " 10baseT loopback mode."}, {0, 0}, }; static void tdk78q2120(long ioaddr, int phy_id) { int mii_reg16 = mii_val[16]; int mii_reg17 = mii_val[17]; int mii_reg18 = mii_val[18]; int i; printf(" TDK format vendor-specific registers 16..18 are " "0x%4.4x 0x%4.4x 0x%4.4x\n", mii_reg16, mii_reg17, mii_reg18); printf(" Link polarity is %s %s.\n" "%s%s" " Auto-negotiation %s, 1%s0Mbps %s duplex.\n" " Rx link in %s state, PLL %s.\n", mii_reg16 & BIT(5) ? "OVERRIDDEN to" : "detected as", mii_reg16 & BIT(4) ? "reversed" : "normal", mii_reg16 & BIT(1) ? " 100baseTx Coding and scrambling is disabled!\n":"", mii_reg16 & BIT(0) ? " Rx_CLK power-save mode is enabled!\n":"", mii_reg18 & BIT(12) ? "had no common media" : "complete", mii_reg18 & BIT(10) ? "0" : "", mii_reg18 & BIT(11) ? "full" : "half", mii_reg18 & BIT(9) ? "pass" : "fail", mii_reg18 & BIT(8) ? "slipped since last read" : "locked"); msg_if_set(mii_reg16, tdk_reg16); if (mii_reg17 & 0x00ff) { printf(" Events since last read:"); for (i = 0; i < 8; i++) if (mii_reg17 & (1 << i)) printf(" %s", tdk_events[i]); } else printf(" No new link status events."); if (mii_reg17 & 0xff00) { printf("\n Events that will raise an interrupt:"); for (i = 0; i < 8; i++) if (mii_reg17 & (0x100 << i)) printf(" %s", tdk_events[i]); } printf("\n"); return; } static void davicom_dm9101(long ioaddr, int phy_id) { printf(" Davicom vendor specific registers: 0x%4.4x 0x%4.4x 0x%4.4x.\n", mii_val[16], mii_val[17], mii_val[18]); } static void intel_i553(long ioaddr, int phy_id) { printf(" This transceiver is 100baseT4 only! Register 16 is %4.4x.\n", mii_val[16]); } /* http://www.enablesemi.com/cgi-bin/byteserve/Products/Docs/3VCardBus.pdf */ static void enablesemi(long ioaddr, int phy_id) { printf(" Isolated %d times, %d false carrier events, %d Rx errors.\n", mii_val[18], mii_val[19], mii_val[21]); printf(" Cable polarity is %s, 100Mb PLL is %slocked.\n", mii_val[28]&BIT(15) ? "reversed" : "normal", mii_val[27]&BIT(13) ? "" : "un"); } /* The amd79c901 contains both PNA and 10/100 management registers. http://www.amd.com/products/npd/techdocs/22304.pdf */ static void amd_pna(long ioaddr, int phy_id) { printf(" HomePNA transceiver in %s speed, %s power mode.\n", mii_val[16] & 4 ? "high" : "low", mii_val[16] & 2 ? "high" : "low"); printf(" HomePNA noise level %d, peak power %d..\n", mii_val[25] >> 8, mii_val[25] & 0xff); } static void amd_tx(long ioaddr, int phy_id) { int mii_reg25 = mii_val[25]; printf(" AMD vendor specific registers: 0x%4.4x 0x%4.4x 0x%4.4x.\n", mii_val[16], mii_val[17], mii_val[18]); printf(" The link is %s in 10%s %s duplex mode, autonegotiation state " "has%s changed.\n", mii_reg25 & 8 ? "up" : "down", mii_reg25 & 1 ? "0baseTx" : "baseT", mii_reg25 & 4 ? "full" : "half", mii_reg25 & 2 ? "" : " not"); } static const struct msg_tbl admtek_reg21[] = { {0x4000, " Link test diabled: Ignoring lack of 10baseT link beat."}, {0x2000, " Link forced up."}, {0x1000, " Tx jabber check disabled."}, {0x0080, " Transmitting 'Far End Fault'!"}, {0x0040, " Rx error count full."}, {0x0008, " Remote loop back enabled."}, {0, 0}, }; static void admtek(long ioaddr, int phy_id) { printf(" ADMtek vendor specific registers information:\n" " Cable length is approximately %d meters.\n" " The receiver has lost lock %d times since last check and " "had %d error events.\n", ((mii_val[20] & 0x00f0) >> 4)*10, mii_val[23], mii_val[23]); msg_if_set(mii_val[21], admtek_reg21); tdk78q2120(ioaddr, phy_id); } static void lu3x31(long ioaddr, int phy_id) { printf(" Lucent vendor specific registers 17: 0x%4.4x" " 29: 0x%4.4x 30: 0x%4.4x 31: 0x%4.4x.\n", mii_val[17], mii_val[29], mii_val[30], mii_val[31]); } static const struct msg_tbl myson_reg16[] = { {0x0080, " Far end fault enabled."}, {0x0040, " Transformer ratio 1.25:1."}, {0x0020, " Polarity correction diabled."}, {0x0010, " Link is forced up regardless of link beat."}, {0x0004, " Bypass Jabber check."}, {0x0001, " 100baseFx mode selected."}, {0, 0}, }; static void myson981(long ioaddr, int phy_id) { int i, mii_reg17 = mii_val[17]; printf(" Myson mtd981 extra registers: %4.4x %4.4x %4.4x %4.4x.\n", mii_val[16], mii_val[17], mii_val[18], mii_val[19]); msg_if_set(mii_val[16] & 0xC800, tdk_reg16); msg_if_set(mii_val[16], myson_reg16); if (mii_reg17 & 0x00ff) { printf(" Events since last read:"); for (i = 0; i < 8; i++) if (mii_reg17 & (1 << i)) printf(" %s", tdk_events[i]); } else printf(" No new link status events."); if (mii_reg17 & 0xff00) { printf("\n Events that will raise an interrupt:"); for (i = 0; i < 8; i++) if (mii_reg17 & (0x100 << i)) printf(" %s", tdk_events[i]); } printf("\n"); return; } /* These are much like the TDK events in reversed order. */ static const struct msg_tbl via_reg17[] = { {0x0001, "Auto-Negotiation complete"}, {0x0002, "Remote fault detected"}, {0x0004, "Link failure detected"}, {0x0008, "Bad Start Stream detected"}, {0x0010, "Parallel detection fault"}, {0x0020, "Extended negotiation page received"}, {0x0040, "5B/4B code error detected"}, {0x0080, "Jabber detected"}, {0, 0}, }; static void via_tahoe(long ioaddr, int phy_id) { int mii_reg16 = mii_val[16]; int mii_reg17 = mii_val[17]; int mii_reg18 = mii_val[18]; printf(" VIA Tahoe extended registers: 16 %4.4x #17 %4.4x #18 %4.4x.\n", mii_reg16, mii_reg17, mii_reg18); msg_if_set_fmt(mii_reg17, via_reg17, " %s\n"); printf(" Link %s 10%s Mbps %s duplex\n", mii_reg18 & BIT(13) ? "up" : "down", mii_reg18 & BIT(10) ? "0" : "", mii_reg18 & BIT(11) ? "full" : "half"); } /* Information from http://www.via.com.tw/en/datasheet/DS6103110.pdf */ static void via_vt6103(long ioaddr, int phy_id) { printf(" VIA vt6103 error counts since the last check:\n" " The link has failed %d times.\n" " The receiver has lost lock %d times.\n" " There have been %d false carrier/SQE error.\n", mii_val[21], mii_val[22], mii_val[23]); } /* Information from http://www.via.com.tw/en/Networking/DS6105LOM100.pdf */ static void via_vt6105(long ioaddr, int phy_id) { printf(" VIA vt6105 PHY status:\n" " Duplex %s speed %s\n", mii_val[20] & BIT(0) ? "full" : "half", mii_val[20] & BIT(1) ? "100" : "10"); } /* Information from http://www.via.com.tw/en/Networking/DS6105LOM100.pdf */ static void intel(long ioaddr, int phy_id) { printf(" Intel 8255* PHY #%d extended management registers:\n" " Error counts, cleared when read:\n" " False carriers %d\n" " Link disconnects %d\n" " Receive errors %d\n" " Rx symbol errors %d.\n" " Rx 10Mbps Early End-Of-Frame errors %d.\n" " Rx 100Mbps Early End-Of-Frame errors %d.\n" " Tx jabber errors %d.\n", mii_val[18], mii_val[19], mii_val[20], mii_val[21], mii_val[22], mii_val[23], mii_val[24], mii_val[25]); } static void mv88x3310_xs(long ioaddr, int phy_id) { DEFINE_C45_PHY(phy, ioaddr, phy_id & ~31, phy_id & 31); if (phy.devad != 4) return; show_c45_subdev(&phy, 2, 0x1000); show_c22_subdev(&phy, 3, 0x2000, &cisco_sgmii_linkword); } static void mv88x3310(long ioaddr, int phy_id) { DEFINE_C45_PHY(phy, ioaddr, phy_id & ~31, phy_id & 31); switch (phy.devad) { case MDIO_MMD_PCS: show_c45_subdev(&phy, 2, 0x1000); show_c22_subdev(&phy, 3, 0x2000, &c37_linkword); break; case MDIO_MMD_AN: show_c45_subdev(&phy, 2, 0x1000); show_c45_subdev(&phy, 3, 0x1800); show_c45_subdev(&phy, 4, 0x2000); printf("\n Other registers"); dump_mii_range(ioaddr, phy_id, 0x8000, 32); dump_mii_range(ioaddr, phy_id, 0x9000, 16); dump_mii_range(ioaddr, phy_id, 0x9800, 16); dump_mii_range(ioaddr, phy_id, 0xa000, 64); break; } } static int marvell_read_paged(const struct phy *phy, unsigned int addr) { u16 val, old_page; long ioaddr = phy->ioaddr; int phy_id = phy->phy_id; old_page = mdio_read(ioaddr, phy_id, 22); mdio_write(ioaddr, phy_id, 22, phy->page); val = mdio_read(ioaddr, phy_id, addr); mdio_write(ioaddr, phy_id, 22, old_page); return val; } static const struct bit_decoder mv88e1111_pss_decoder[] = { { 0xc800, 0x8800, "1000Mbps" }, { 0xc800, 0x4800, "100Mbps" }, { 0xc800, 0x0800, "10Mbps" }, { 0x2800, 0x2800, "Full" }, { 0x2800, 0x0800, "Half" }, { 0x0400, 0x0400, "Link Up" }, { 0x0440, 0x0440, "MDIX" }, { 0x0440, 0x0400, "MDI" }, { 0x0420, 0x0420, "Downshift" }, { 0x0808, 0x0808, "TX Pause" }, { 0x0804, 0x0804, "RX Pause" }, { }, }; static const struct bit_decoder mv88e1111_epss_decoder[] = { { 0x8000, 0x8000, "Fiber/copper auto-selection disabled" }, { 0x8000, 0x0000, "Fiber/copper auto-selection enabled" }, { 0x2000, 0x2000, "Fiber link selected" }, { 0x2000, 0x0000, "Copper link selected" }, { 0x1000, 0x1000, "AN bypass enabled" }, { 0x1000, 0x0000, "AN bypass disabled" }, { 0x0800, 0x0800, "AN is bypassed" }, { 0x0200, 0x0200, "Auto-medium register selection enabled" }, { 0x000f, 0x0000, "SGMII w/ clock w/ SGMII AN to copper" }, { 0x000f, 0x0003, "RGMII to fiber" }, { 0x000f, 0x0004, "SGMII w/o clock w/ SGMII AN to copper" }, { 0x000f, 0x0006, "RGMII to SGMII" }, { 0x000f, 0x0007, "GMII to fiber" }, { 0x000f, 0x0008, "1000baseX w/o clock w/ 1000baseX AN to copper" }, { 0x000f, 0x0009, "RTBI to copper" }, { 0x000f, 0x000b, "RGMII/Modified MII to copper" }, { 0x000f, 0x000c, "1000baseX w/o clock w/o 1000baseX AN to copper" }, { 0x000f, 0x000d, "TBI to copper" }, { 0x000f, 0x000e, "GMII to SGMII" }, { 0x000f, 0x000f, "GMII to copper" }, { }, }; static void mv88e1111(long ioaddr, int phy_id) { DEFINE_C22_PHY(phy, ioaddr, phy_id); int i; show_mii_reg("PHY Specific Status", mii_val[17], mv88e1111_pss_decoder, "\n ", ", "); show_mii_reg("Extended PHY Specific Status", mii_val[27], mv88e1111_epss_decoder, " ", ".\n "); phy.page = 1; phy.mdio_read = marvell_read_paged; for (i = 0; i < 32; i++) mii_val[i] = mdio_read_phy(&phy, i); printf("\n MII PHY #%d fiber registers:", phy_id); show_mii_regs(32); printf(".\n"); switch (mii_val[27] & 15) { case 0: case 4: /* SGMII to copper */ show_mii_c22_details(&phy, &cisco_sgmii_linkword); break; case 8: case 12: /* GMII mode */ show_mii_c22_details(&phy, &c37_linkword); break; default: break; } } static const struct bit_decoder mv88e151x_gcr[] = { { 0x0040, 0x0040, "Auto-media:" }, { 0x0070, 0x0040, "Link on first media" }, { 0x0070, 0x0050, "Copper preferred" }, { 0x0070, 0x0060, "Fiber preferred" }, { 0x0070, 0x0070, "Reserved" }, { 0x0007, 0x0000, "RGMII(sys) to Copper" }, { 0x0007, 0x0001, "SGMII(sys) to Copper" }, { 0x0007, 0x0002, "RGMII(sys) to 1000baseX" }, { 0x0007, 0x0003, "SGMII(sys) to 100baseFX" }, { 0x0007, 0x0004, "SGMII(sys) to SGMII(media)" }, { 0x0007, 0x0005, "Reserved" }, { 0x0007, 0x0006, "RGMII(sys) to Auto" }, { 0x0007, 0x0007, "RGMII(sys) to Auto" }, { }, }; static const struct bit_decoder marvell_sgmii_adv_decoder[] = { { 0x8000, 0x0000, "Link Down" }, { 0x8000, 0x8000, "Link Up, " }, { 0x8c00, 0x8000, "10M/" }, { 0x8c00, 0x8400, "100M/" }, { 0x8c00, 0x8800, "1000M/" }, { 0x8c00, 0x8c00, "?/" }, { 0x9000, 0x8000, "Half, " }, { 0x9000, 0x9000, "Full, " }, /* These are the Marvell additions */ { 0x8200, 0x8200, "TxPause, " }, { 0x8100, 0x8100, "RxPause, " }, { 0x8080, 0x8000, "Copper" }, { 0x8080, 0x8080, "Fiber" }, { }, }; static void marvell_sgmii_advert(struct phy *phy, u16 *regs) { const char *strings[17], **p = strings; u16 base = regs[4]; printf(" SGMII advertisement %4.4x", base); if (base & 1) { p = bit_decoder(p, base, marvell_sgmii_adv_decoder); } else { *p++ = " Link down"; *p = NULL; } if (base & 0x607e) { *p++ = ", reserved bits are set"; *p = NULL; } print_strings(strings, ": ", ""); } static const struct c22_decoder marvell_system_sgmii_linkword = { .show_advert = marvell_sgmii_advert, .show_lpar = cisco_sgmii_lpar, }; static const struct bit_decoder marvell_fscr2_decoder[] = { { 0x4000, 0x4000, "1000baseX noise filter" }, { 0x0200, 0x0200, "100baseFX FEFI enabled" }, { 0x0040, 0x0040, "AN bypass enabled" }, { 0x0040, 0x0000, "AN bypass disabled" }, { 0x0020, 0x0020, "AN was bypassed" }, { 0x0008, 0x0008, "Fiber TX disabled" }, { }, }; static void mv88e151x(long ioaddr, int phy_id) { DEFINE_C22_PHY(phy, ioaddr, phy_id); u16 gcr; int i; phy.page = 18; gcr = mdio_read_phy(&phy, 20); show_mii_reg("General Control Register 1", gcr, mv88e151x_gcr, ": ", ", "); phy.page = 1; phy.mdio_read = marvell_read_paged; for (i = 0; i < 32; i++) mii_val[i] = mdio_read_phy(&phy, i); printf("\n MII PHY #%d fiber registers:", phy_id); show_mii_regs(32); printf(".\n"); switch (mii_val[16] & 3) { case 0: /* 100baseFX */ break; case 1: /* 1000baseX */ show_mii_c22_details(&phy, &c37_linkword); break; case 2: /* SGMII System mode */ show_mii_c22_details(&phy, &marvell_system_sgmii_linkword); break; case 3: /* SGMII Media mode */ show_mii_c22_details(&phy, &cisco_sgmii_linkword); break; } show_mii_reg("Fiber Specific Control Register 2", mii_val[26], marvell_fscr2_decoder, ": ", ", "); } /* * Local variables: * compile-command: "cc -O -Wall -c libmii.c" * c-indent-level: 4 * c-basic-offset: 4 * tab-width: 4 * End: */