sme.c revision 1.2.4.2
1 1.2.4.2 bouyer /* $NetBSD: sme.c,v 1.2.4.2 2011/03/06 15:07:56 bouyer Exp $ */ 2 1.2.4.2 bouyer 3 1.2.4.2 bouyer /*- 4 1.2.4.2 bouyer * Copyright (c) 2008 The NetBSD Foundation, Inc. 5 1.2.4.2 bouyer * All rights reserved. 6 1.2.4.2 bouyer * 7 1.2.4.2 bouyer * This code is derived from software contributed to The NetBSD Foundation 8 1.2.4.2 bouyer * by Tohru Nishimura. 9 1.2.4.2 bouyer * 10 1.2.4.2 bouyer * Redistribution and use in source and binary forms, with or without 11 1.2.4.2 bouyer * modification, are permitted provided that the following conditions 12 1.2.4.2 bouyer * are met: 13 1.2.4.2 bouyer * 1. Redistributions of source code must retain the above copyright 14 1.2.4.2 bouyer * notice, this list of conditions and the following disclaimer. 15 1.2.4.2 bouyer * 2. Redistributions in binary form must reproduce the above copyright 16 1.2.4.2 bouyer * notice, this list of conditions and the following disclaimer in the 17 1.2.4.2 bouyer * documentation and/or other materials provided with the distribution. 18 1.2.4.2 bouyer * 19 1.2.4.2 bouyer * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 20 1.2.4.2 bouyer * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 21 1.2.4.2 bouyer * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 22 1.2.4.2 bouyer * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 23 1.2.4.2 bouyer * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 24 1.2.4.2 bouyer * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 25 1.2.4.2 bouyer * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 26 1.2.4.2 bouyer * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 27 1.2.4.2 bouyer * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 28 1.2.4.2 bouyer * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 29 1.2.4.2 bouyer * POSSIBILITY OF SUCH DAMAGE. 30 1.2.4.2 bouyer */ 31 1.2.4.2 bouyer 32 1.2.4.2 bouyer #include <sys/param.h> 33 1.2.4.2 bouyer 34 1.2.4.2 bouyer #include <netinet/in.h> 35 1.2.4.2 bouyer #include <netinet/in_systm.h> 36 1.2.4.2 bouyer 37 1.2.4.2 bouyer #include <lib/libsa/stand.h> 38 1.2.4.2 bouyer #include <lib/libsa/net.h> 39 1.2.4.2 bouyer 40 1.2.4.2 bouyer #include "globals.h" 41 1.2.4.2 bouyer 42 1.2.4.2 bouyer /* 43 1.2.4.2 bouyer * - reverse endian access every CSR. 44 1.2.4.2 bouyer * - no VTOPHYS() translation, vaddr_t == paddr_t. 45 1.2.4.2 bouyer * - PIPT writeback cache aware. 46 1.2.4.2 bouyer */ 47 1.2.4.2 bouyer #define CSR_READ(l, r) in32rb((l)->csr+(r)) 48 1.2.4.2 bouyer #define CSR_WRITE(l, r, v) out32rb((l)->csr+(r), (v)) 49 1.2.4.2 bouyer #define VTOPHYS(va) (uint32_t)(va) 50 1.2.4.2 bouyer #define DEVTOV(pa) (uint32_t)(pa) 51 1.2.4.2 bouyer #define wbinv(adr, siz) _wbinv(VTOPHYS(adr), (uint32_t)(siz)) 52 1.2.4.2 bouyer #define inv(adr, siz) _inv(VTOPHYS(adr), (uint32_t)(siz)) 53 1.2.4.2 bouyer #define DELAY(n) delay(n) 54 1.2.4.2 bouyer #define ALLOC(T,A) (T *)allocaligned(sizeof(T),(A)) 55 1.2.4.2 bouyer 56 1.2.4.2 bouyer struct desc { 57 1.2.4.2 bouyer uint32_t xd0, xd1, xd2, xd3; 58 1.2.4.2 bouyer }; 59 1.2.4.2 bouyer #define T0_OWN (1U<<31) /* */ 60 1.2.4.2 bouyer #define T0_ES (1U<<15) /* error summary */ 61 1.2.4.2 bouyer #define T0_FL 0x7fff0000 /* frame length */ 62 1.2.4.2 bouyer #define T1_LS (1U<<30) /* last descriptor of Tx frame */ 63 1.2.4.2 bouyer #define T1_FS (1U<<29) /* first descriptor of Tx frame */ 64 1.2.4.2 bouyer #define T1_TER (1U<<25) /* wrap mark to form a ring */ 65 1.2.4.2 bouyer #define T1_TCH (1U<<24) /* TDES3 points the next desc */ 66 1.2.4.2 bouyer #define T1_FL 0x00007ff /* Tx frame/segment length */ 67 1.2.4.2 bouyer #define R0_OWN (1U<<31) /* */ 68 1.2.4.2 bouyer #define R0_FL 0x3fff0000 /* frame length */ 69 1.2.4.2 bouyer #define R0_ES (1U<<15) /* error summary */ 70 1.2.4.2 bouyer #define R1_RER (1U<<25) /* wrap mark to form a ring */ 71 1.2.4.2 bouyer #define R1_RCH (1U<<24) /* RDES3 points the next desc */ 72 1.2.4.2 bouyer /* RDES1 will be never changed while operation */ 73 1.2.4.2 bouyer 74 1.2.4.2 bouyer #define BUSMODE 0x00 75 1.2.4.2 bouyer #define TXPOLLD 0x04 /* start transmission */ 76 1.2.4.2 bouyer #define RXPOLLD 0x08 /* start receiving */ 77 1.2.4.2 bouyer #define RXDBASE 0x0c /* Rx descriptor list base */ 78 1.2.4.2 bouyer #define TXDBASE 0x10 /* Tx descriptor list base */ 79 1.2.4.2 bouyer #define DMACCTL 0x18 /* DMAC control */ 80 1.2.4.2 bouyer #define DMACCTL_ST (1U<<13) /* start/stop Tx DMA */ 81 1.2.4.2 bouyer #define DMACCTL_SR (1U<< 1) /* start/stop Rx DMA */ 82 1.2.4.2 bouyer #define MAC_CR 0x80 /* MAC control */ 83 1.2.4.2 bouyer #define MACCR_FDPX (1U<<20) /* full duplex operation */ 84 1.2.4.2 bouyer #define MACCR_TXEN (1U<< 3) /* enable xmit */ 85 1.2.4.2 bouyer #define MACCR_RXEN (1U<< 2) /* enable recv */ 86 1.2.4.2 bouyer #define ADDRH 0x84 /* ea 5:4 */ 87 1.2.4.2 bouyer #define ADDRL 0x88 /* ea 3:0 */ 88 1.2.4.2 bouyer #define MIIADDR 0x94 /* MII control */ 89 1.2.4.2 bouyer #define MIIDATA 0x98 /* MII data */ 90 1.2.4.2 bouyer 91 1.2.4.2 bouyer #define FRAMESIZE 1536 92 1.2.4.2 bouyer 93 1.2.4.2 bouyer struct local { 94 1.2.4.2 bouyer struct desc txd[2]; 95 1.2.4.2 bouyer struct desc rxd[2]; 96 1.2.4.2 bouyer uint8_t rxstore[2][FRAMESIZE]; 97 1.2.4.2 bouyer unsigned csr, tx, rx; 98 1.2.4.2 bouyer unsigned phy, bmsr, anlpar; 99 1.2.4.2 bouyer }; 100 1.2.4.2 bouyer 101 1.2.4.2 bouyer static int mii_read(struct local *, int, int); 102 1.2.4.2 bouyer static void mii_write(struct local *, int, int, int); 103 1.2.4.2 bouyer static void mii_dealan(struct local *, unsigned); 104 1.2.4.2 bouyer 105 1.2.4.2 bouyer int 106 1.2.4.2 bouyer sme_match(unsigned tag, void *data) 107 1.2.4.2 bouyer { 108 1.2.4.2 bouyer unsigned v; 109 1.2.4.2 bouyer 110 1.2.4.2 bouyer v = pcicfgread(tag, PCI_ID_REG); 111 1.2.4.2 bouyer switch (v) { 112 1.2.4.2 bouyer case PCI_DEVICE(0x1055, 0xe940): 113 1.2.4.2 bouyer return 1; 114 1.2.4.2 bouyer } 115 1.2.4.2 bouyer return 0; 116 1.2.4.2 bouyer } 117 1.2.4.2 bouyer 118 1.2.4.2 bouyer void * 119 1.2.4.2 bouyer sme_init(unsigned tag, void *data) 120 1.2.4.2 bouyer { 121 1.2.4.2 bouyer struct local *l; 122 1.2.4.2 bouyer struct desc *txd, *rxd; 123 1.2.4.2 bouyer unsigned mac32, mac16, val, fdx; 124 1.2.4.2 bouyer uint8_t *en; 125 1.2.4.2 bouyer 126 1.2.4.2 bouyer l = ALLOC(struct local, 32); /* desc alignment */ 127 1.2.4.2 bouyer memset(l, 0, sizeof(struct local)); 128 1.2.4.2 bouyer l->csr = DEVTOV(pcicfgread(tag, 0x1c)); /* BAR3 mem space, LE */ 129 1.2.4.2 bouyer l->phy = 1; /* 9420 internal PHY */ 130 1.2.4.2 bouyer 131 1.2.4.2 bouyer en = data; 132 1.2.4.2 bouyer mac32 = CSR_READ(l, ADDRL); 133 1.2.4.2 bouyer mac16 = CSR_READ(l, ADDRH); 134 1.2.4.2 bouyer en[0] = mac32; 135 1.2.4.2 bouyer en[1] = mac32 >> 8; 136 1.2.4.2 bouyer en[2] = mac32 >> 16; 137 1.2.4.2 bouyer en[3] = mac32 >> 24; 138 1.2.4.2 bouyer en[4] = mac16; 139 1.2.4.2 bouyer en[5] = mac16 >> 8; 140 1.2.4.2 bouyer 141 1.2.4.2 bouyer printf("MAC address %02x:%02x:%02x:%02x:%02x:%02x\n", 142 1.2.4.2 bouyer en[0], en[1], en[2], en[3], en[4], en[5]); 143 1.2.4.2 bouyer DPRINTF(("PHY %d (%04x.%04x)\n", l->phy, 144 1.2.4.2 bouyer mii_read(l, l->phy, 2), mii_read(l, l->phy, 3))); 145 1.2.4.2 bouyer 146 1.2.4.2 bouyer mii_dealan(l, 5); 147 1.2.4.2 bouyer 148 1.2.4.2 bouyer /* speed and duplexity can be seen in MII 31 */ 149 1.2.4.2 bouyer val = mii_read(l, l->phy, 31); 150 1.2.4.2 bouyer fdx = !!(val & (1U << 4)); 151 1.2.4.2 bouyer printf("%s", (val & (1U << 3)) ? "100Mbps" : "10Mbps"); 152 1.2.4.2 bouyer if (fdx) 153 1.2.4.2 bouyer printf("-FDX"); 154 1.2.4.2 bouyer printf("\n"); 155 1.2.4.2 bouyer 156 1.2.4.2 bouyer txd = &l->txd[0]; 157 1.2.4.2 bouyer rxd = &l->rxd[0]; 158 1.2.4.2 bouyer rxd[0].xd0 = htole32(R0_OWN); 159 1.2.4.2 bouyer rxd[0].xd1 = htole32(R1_RCH | FRAMESIZE); 160 1.2.4.2 bouyer rxd[0].xd2 = htole32(VTOPHYS(l->rxstore[0])); 161 1.2.4.2 bouyer rxd[0].xd3 = htole32(VTOPHYS(&rxd[1])); 162 1.2.4.2 bouyer rxd[1].xd0 = htole32(R0_OWN); 163 1.2.4.2 bouyer rxd[1].xd1 = htole32(R1_RER | FRAMESIZE); 164 1.2.4.2 bouyer rxd[1].xd2 = htole32(VTOPHYS(l->rxstore[1])); 165 1.2.4.2 bouyer /* R1_RER neglects xd3 */ 166 1.2.4.2 bouyer l->tx = l->rx = 0; 167 1.2.4.2 bouyer 168 1.2.4.2 bouyer wbinv(l, sizeof(struct local)); 169 1.2.4.2 bouyer 170 1.2.4.2 bouyer CSR_WRITE(l, TXDBASE, VTOPHYS(txd)); 171 1.2.4.2 bouyer CSR_WRITE(l, RXDBASE, VTOPHYS(rxd)); 172 1.2.4.2 bouyer val = MACCR_TXEN | MACCR_RXEN; 173 1.2.4.2 bouyer if (fdx) 174 1.2.4.2 bouyer val |= MACCR_FDPX; 175 1.2.4.2 bouyer CSR_WRITE(l, BUSMODE, 0); 176 1.2.4.2 bouyer CSR_WRITE(l, DMACCTL, DMACCTL_ST | DMACCTL_SR); 177 1.2.4.2 bouyer CSR_WRITE(l, MAC_CR, val); /* (FDX), Tx/Rx enable */ 178 1.2.4.2 bouyer CSR_WRITE(l, RXPOLLD, 01); /* start receiving */ 179 1.2.4.2 bouyer 180 1.2.4.2 bouyer return l; 181 1.2.4.2 bouyer } 182 1.2.4.2 bouyer 183 1.2.4.2 bouyer int 184 1.2.4.2 bouyer sme_send(void *dev, char *buf, unsigned len) 185 1.2.4.2 bouyer { 186 1.2.4.2 bouyer struct local *l = dev; 187 1.2.4.2 bouyer volatile struct desc *txd; 188 1.2.4.2 bouyer unsigned txstat, loop; 189 1.2.4.2 bouyer 190 1.2.4.2 bouyer /* send a single frame with no T1_TER|T1_TCH designation */ 191 1.2.4.2 bouyer wbinv(buf, len); 192 1.2.4.2 bouyer txd = &l->txd[l->tx]; 193 1.2.4.2 bouyer txd->xd2 = htole32(VTOPHYS(buf)); 194 1.2.4.2 bouyer txd->xd1 = htole32(T1_FS | T1_LS | (len & T1_FL)); 195 1.2.4.2 bouyer txd->xd0 = htole32(T0_OWN | (len & T0_FL) << 16); 196 1.2.4.2 bouyer wbinv(txd, sizeof(struct desc)); 197 1.2.4.2 bouyer CSR_WRITE(l, TXPOLLD, 01); /* start transmission */ 198 1.2.4.2 bouyer loop = 100; 199 1.2.4.2 bouyer do { 200 1.2.4.2 bouyer txstat = le32toh(txd->xd0); 201 1.2.4.2 bouyer if (txstat & T0_ES) 202 1.2.4.2 bouyer break; 203 1.2.4.2 bouyer if ((txstat & T0_OWN) == 0) 204 1.2.4.2 bouyer goto done; 205 1.2.4.2 bouyer DELAY(10); 206 1.2.4.2 bouyer inv(txd, sizeof(struct desc)); 207 1.2.4.2 bouyer } while (--loop != 0); 208 1.2.4.2 bouyer printf("xmit failed\n"); 209 1.2.4.2 bouyer return -1; 210 1.2.4.2 bouyer done: 211 1.2.4.2 bouyer l->tx ^= 1; 212 1.2.4.2 bouyer return len; 213 1.2.4.2 bouyer } 214 1.2.4.2 bouyer 215 1.2.4.2 bouyer int 216 1.2.4.2 bouyer sme_recv(void *dev, char *buf, unsigned maxlen, unsigned timo) 217 1.2.4.2 bouyer { 218 1.2.4.2 bouyer struct local *l = dev; 219 1.2.4.2 bouyer volatile struct desc *rxd; 220 1.2.4.2 bouyer unsigned bound, rxstat, len; 221 1.2.4.2 bouyer uint8_t *ptr; 222 1.2.4.2 bouyer 223 1.2.4.2 bouyer bound = 1000 * timo; 224 1.2.4.2 bouyer printf("recving with %u sec. timeout\n", timo); 225 1.2.4.2 bouyer again: 226 1.2.4.2 bouyer rxd = &l->rxd[l->rx]; 227 1.2.4.2 bouyer do { 228 1.2.4.2 bouyer inv(rxd, sizeof(struct desc)); 229 1.2.4.2 bouyer rxstat = le32toh(rxd->xd0); 230 1.2.4.2 bouyer if ((rxstat & R0_OWN) == 0) 231 1.2.4.2 bouyer goto gotone; 232 1.2.4.2 bouyer DELAY(1000); /* 1 milli second */ 233 1.2.4.2 bouyer } while (--bound > 0); 234 1.2.4.2 bouyer errno = 0; 235 1.2.4.2 bouyer return -1; 236 1.2.4.2 bouyer gotone: 237 1.2.4.2 bouyer if (rxstat & R0_ES) { 238 1.2.4.2 bouyer rxd->xd0 = htole32(R0_OWN); 239 1.2.4.2 bouyer wbinv(rxd, sizeof(struct desc)); 240 1.2.4.2 bouyer l->rx ^= 1; 241 1.2.4.2 bouyer CSR_WRITE(l, RXPOLLD, 01); /* restart receiving */ 242 1.2.4.2 bouyer goto again; 243 1.2.4.2 bouyer } 244 1.2.4.2 bouyer /* good frame */ 245 1.2.4.2 bouyer len = (rxstat & R0_FL) >> 16 /* no FCS included */; 246 1.2.4.2 bouyer if (len > maxlen) 247 1.2.4.2 bouyer len = maxlen; 248 1.2.4.2 bouyer ptr = l->rxstore[l->rx]; 249 1.2.4.2 bouyer inv(ptr, len); 250 1.2.4.2 bouyer memcpy(buf, ptr, len); 251 1.2.4.2 bouyer rxd->xd0 = htole32(R0_OWN); 252 1.2.4.2 bouyer wbinv(rxd, sizeof(struct desc)); 253 1.2.4.2 bouyer l->rx ^= 1; 254 1.2.4.2 bouyer CSR_WRITE(l, RXPOLLD, 01); /* necessary? */ 255 1.2.4.2 bouyer return len; 256 1.2.4.2 bouyer } 257 1.2.4.2 bouyer 258 1.2.4.2 bouyer #define MII_BMCR 0x00 /* Basic mode control register (rw) */ 259 1.2.4.2 bouyer #define BMCR_RESET 0x8000 /* reset */ 260 1.2.4.2 bouyer #define BMCR_AUTOEN 0x1000 /* autonegotiation enable */ 261 1.2.4.2 bouyer #define BMCR_ISO 0x0400 /* isolate */ 262 1.2.4.2 bouyer #define BMCR_STARTNEG 0x0200 /* restart autonegotiation */ 263 1.2.4.2 bouyer #define MII_BMSR 0x01 /* Basic mode status register (ro) */ 264 1.2.4.2 bouyer #define BMSR_ACOMP 0x0020 /* Autonegotiation complete */ 265 1.2.4.2 bouyer #define BMSR_LINK 0x0004 /* Link status */ 266 1.2.4.2 bouyer #define MII_ANAR 0x04 /* Autonegotiation advertisement (rw) */ 267 1.2.4.2 bouyer #define ANAR_FC 0x0400 /* local device supports PAUSE */ 268 1.2.4.2 bouyer #define ANAR_TX_FD 0x0100 /* local device supports 100bTx FD */ 269 1.2.4.2 bouyer #define ANAR_TX 0x0080 /* local device supports 100bTx */ 270 1.2.4.2 bouyer #define ANAR_10_FD 0x0040 /* local device supports 10bT FD */ 271 1.2.4.2 bouyer #define ANAR_10 0x0020 /* local device supports 10bT */ 272 1.2.4.2 bouyer #define ANAR_CSMA 0x0001 /* protocol selector CSMA/CD */ 273 1.2.4.2 bouyer #define MII_ANLPAR 0x05 /* Autonegotiation lnk partner abilities (rw) */ 274 1.2.4.2 bouyer 275 1.2.4.2 bouyer static int 276 1.2.4.2 bouyer mii_read(struct local *l, int phy, int reg) 277 1.2.4.2 bouyer { 278 1.2.4.2 bouyer uint32_t ctl; 279 1.2.4.2 bouyer 280 1.2.4.2 bouyer do { 281 1.2.4.2 bouyer ctl = CSR_READ(l, MIIADDR); 282 1.2.4.2 bouyer } while (ctl & 01); 283 1.2.4.2 bouyer ctl = (phy << 11) | (reg << 6) | (0 << 1); /* READ op */ 284 1.2.4.2 bouyer CSR_WRITE(l, MIIADDR, ctl); 285 1.2.4.2 bouyer do { 286 1.2.4.2 bouyer ctl = CSR_READ(l, MIIADDR); 287 1.2.4.2 bouyer } while (ctl & 01); 288 1.2.4.2 bouyer return CSR_READ(l, MIIDATA); 289 1.2.4.2 bouyer } 290 1.2.4.2 bouyer 291 1.2.4.2 bouyer void 292 1.2.4.2 bouyer mii_write(struct local *l, int phy, int reg, int val) 293 1.2.4.2 bouyer { 294 1.2.4.2 bouyer uint32_t ctl; 295 1.2.4.2 bouyer 296 1.2.4.2 bouyer do { 297 1.2.4.2 bouyer ctl = CSR_READ(l, MIIADDR); 298 1.2.4.2 bouyer } while (ctl & 01); 299 1.2.4.2 bouyer ctl = (phy << 11) | (reg << 6) | (1 << 1); /* WRITE op */ 300 1.2.4.2 bouyer CSR_WRITE(l, MIIDATA, val); 301 1.2.4.2 bouyer } 302 1.2.4.2 bouyer 303 1.2.4.2 bouyer void 304 1.2.4.2 bouyer mii_dealan(struct local *l, unsigned timo) 305 1.2.4.2 bouyer { 306 1.2.4.2 bouyer unsigned anar, bound; 307 1.2.4.2 bouyer 308 1.2.4.2 bouyer anar = ANAR_TX_FD | ANAR_TX | ANAR_10_FD | ANAR_10 | ANAR_CSMA; 309 1.2.4.2 bouyer mii_write(l, l->phy, MII_ANAR, anar); 310 1.2.4.2 bouyer mii_write(l, l->phy, MII_BMCR, BMCR_AUTOEN | BMCR_STARTNEG); 311 1.2.4.2 bouyer l->anlpar = 0; 312 1.2.4.2 bouyer bound = getsecs() + timo; 313 1.2.4.2 bouyer do { 314 1.2.4.2 bouyer l->bmsr = mii_read(l, l->phy, MII_BMSR) | 315 1.2.4.2 bouyer mii_read(l, l->phy, MII_BMSR); /* read twice */ 316 1.2.4.2 bouyer if ((l->bmsr & BMSR_LINK) && (l->bmsr & BMSR_ACOMP)) { 317 1.2.4.2 bouyer l->anlpar = mii_read(l, l->phy, MII_ANLPAR); 318 1.2.4.2 bouyer break; 319 1.2.4.2 bouyer } 320 1.2.4.2 bouyer DELAY(10 * 1000); 321 1.2.4.2 bouyer } while (getsecs() < bound); 322 1.2.4.2 bouyer return; 323 1.2.4.2 bouyer } 324
Indexes created Mon Oct 13 21:09:55 GMT 2025