pq3etsec.c revision 1.21
1 1.21 nonaka /* $NetBSD: pq3etsec.c,v 1.21 2015/01/16 05:50:15 nonaka Exp $ */ 2 1.2 matt /*- 3 1.2 matt * Copyright (c) 2010, 2011 The NetBSD Foundation, Inc. 4 1.2 matt * All rights reserved. 5 1.2 matt * 6 1.2 matt * This code is derived from software contributed to The NetBSD Foundation 7 1.2 matt * by Raytheon BBN Technologies Corp and Defense Advanced Research Projects 8 1.2 matt * Agency and which was developed by Matt Thomas of 3am Software Foundry. 9 1.2 matt * 10 1.2 matt * This material is based upon work supported by the Defense Advanced Research 11 1.2 matt * Projects Agency and Space and Naval Warfare Systems Center, Pacific, under 12 1.2 matt * Contract No. N66001-09-C-2073. 13 1.2 matt * Approved for Public Release, Distribution Unlimited 14 1.2 matt * 15 1.2 matt * Redistribution and use in source and binary forms, with or without 16 1.2 matt * modification, are permitted provided that the following conditions 17 1.2 matt * are met: 18 1.2 matt * 1. Redistributions of source code must retain the above copyright 19 1.2 matt * notice, this list of conditions and the following disclaimer. 20 1.2 matt * 2. Redistributions in binary form must reproduce the above copyright 21 1.2 matt * notice, this list of conditions and the following disclaimer in the 22 1.2 matt * documentation and/or other materials provided with the distribution. 23 1.2 matt * 24 1.2 matt * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 25 1.2 matt * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 26 1.2 matt * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 27 1.2 matt * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 28 1.2 matt * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 29 1.2 matt * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 30 1.2 matt * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 31 1.2 matt * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 32 1.2 matt * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 33 1.2 matt * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 34 1.2 matt * POSSIBILITY OF SUCH DAMAGE. 35 1.2 matt */ 36 1.2 matt 37 1.2 matt #include "opt_inet.h" 38 1.15 matt #include "opt_mpc85xx.h" 39 1.2 matt 40 1.2 matt #include <sys/cdefs.h> 41 1.2 matt 42 1.21 nonaka __KERNEL_RCSID(0, "$NetBSD: pq3etsec.c,v 1.21 2015/01/16 05:50:15 nonaka Exp $"); 43 1.7 matt 44 1.2 matt #include <sys/param.h> 45 1.2 matt #include <sys/cpu.h> 46 1.2 matt #include <sys/device.h> 47 1.2 matt #include <sys/mbuf.h> 48 1.2 matt #include <sys/ioctl.h> 49 1.2 matt #include <sys/intr.h> 50 1.2 matt #include <sys/bus.h> 51 1.2 matt #include <sys/kernel.h> 52 1.2 matt #include <sys/kmem.h> 53 1.2 matt #include <sys/proc.h> 54 1.2 matt #include <sys/atomic.h> 55 1.2 matt #include <sys/callout.h> 56 1.2 matt 57 1.2 matt #include <net/if.h> 58 1.2 matt #include <net/if_dl.h> 59 1.2 matt #include <net/if_ether.h> 60 1.2 matt #include <net/if_media.h> 61 1.2 matt 62 1.2 matt #include <dev/mii/miivar.h> 63 1.2 matt 64 1.2 matt #include <net/bpf.h> 65 1.2 matt 66 1.2 matt #ifdef INET 67 1.2 matt #include <netinet/in.h> 68 1.2 matt #include <netinet/in_systm.h> 69 1.2 matt #include <netinet/ip.h> 70 1.2 matt #include <netinet/in_offload.h> 71 1.2 matt #endif /* INET */ 72 1.2 matt #ifdef INET6 73 1.2 matt #include <netinet6/in6.h> 74 1.2 matt #include <netinet/ip6.h> 75 1.2 matt #endif 76 1.2 matt #include <netinet6/in6_offload.h> 77 1.2 matt 78 1.2 matt 79 1.2 matt #include <powerpc/spr.h> 80 1.2 matt #include <powerpc/booke/spr.h> 81 1.2 matt 82 1.2 matt #include <powerpc/booke/cpuvar.h> 83 1.2 matt #include <powerpc/booke/e500var.h> 84 1.2 matt #include <powerpc/booke/e500reg.h> 85 1.2 matt #include <powerpc/booke/etsecreg.h> 86 1.2 matt 87 1.2 matt #define M_HASFCB M_LINK2 /* tx packet has FCB prepended */ 88 1.2 matt 89 1.2 matt #define ETSEC_MAXTXMBUFS 30 90 1.2 matt #define ETSEC_NTXSEGS 30 91 1.2 matt #define ETSEC_MAXRXMBUFS 511 92 1.2 matt #define ETSEC_MINRXMBUFS 32 93 1.2 matt #define ETSEC_NRXSEGS 1 94 1.2 matt 95 1.2 matt #define IFCAP_RCTRL_IPCSEN IFCAP_CSUM_IPv4_Rx 96 1.2 matt #define IFCAP_RCTRL_TUCSEN (IFCAP_CSUM_TCPv4_Rx\ 97 1.2 matt |IFCAP_CSUM_UDPv4_Rx\ 98 1.2 matt |IFCAP_CSUM_TCPv6_Rx\ 99 1.2 matt |IFCAP_CSUM_UDPv6_Rx) 100 1.2 matt 101 1.2 matt #define IFCAP_TCTRL_IPCSEN IFCAP_CSUM_IPv4_Tx 102 1.2 matt #define IFCAP_TCTRL_TUCSEN (IFCAP_CSUM_TCPv4_Tx\ 103 1.2 matt |IFCAP_CSUM_UDPv4_Tx\ 104 1.2 matt |IFCAP_CSUM_TCPv6_Tx\ 105 1.2 matt |IFCAP_CSUM_UDPv6_Tx) 106 1.2 matt 107 1.2 matt #define IFCAP_ETSEC (IFCAP_RCTRL_IPCSEN|IFCAP_RCTRL_TUCSEN\ 108 1.2 matt |IFCAP_TCTRL_IPCSEN|IFCAP_TCTRL_TUCSEN) 109 1.2 matt 110 1.2 matt #define M_CSUM_IP (M_CSUM_CIP|M_CSUM_CTU) 111 1.2 matt #define M_CSUM_IP6 (M_CSUM_TCPv6|M_CSUM_UDPv6) 112 1.2 matt #define M_CSUM_TUP (M_CSUM_TCPv4|M_CSUM_UDPv4|M_CSUM_TCPv6|M_CSUM_UDPv6) 113 1.2 matt #define M_CSUM_UDP (M_CSUM_UDPv4|M_CSUM_UDPv6) 114 1.2 matt #define M_CSUM_IP4 (M_CSUM_IPv4|M_CSUM_UDPv4|M_CSUM_TCPv4) 115 1.2 matt #define M_CSUM_CIP (M_CSUM_IPv4) 116 1.2 matt #define M_CSUM_CTU (M_CSUM_TCPv4|M_CSUM_UDPv4|M_CSUM_TCPv6|M_CSUM_UDPv6) 117 1.2 matt 118 1.2 matt struct pq3etsec_txqueue { 119 1.2 matt bus_dmamap_t txq_descmap; 120 1.2 matt volatile struct txbd *txq_consumer; 121 1.2 matt volatile struct txbd *txq_producer; 122 1.2 matt volatile struct txbd *txq_first; 123 1.2 matt volatile struct txbd *txq_last; 124 1.2 matt struct ifqueue txq_mbufs; 125 1.2 matt struct mbuf *txq_next; 126 1.2 matt #ifdef ETSEC_DEBUG 127 1.2 matt struct mbuf *txq_lmbufs[512]; 128 1.2 matt #endif 129 1.2 matt uint32_t txq_qmask; 130 1.2 matt uint32_t txq_free; 131 1.2 matt uint32_t txq_threshold; 132 1.2 matt uint32_t txq_lastintr; 133 1.2 matt bus_size_t txq_reg_tbase; 134 1.2 matt bus_dma_segment_t txq_descmap_seg; 135 1.2 matt }; 136 1.2 matt 137 1.2 matt struct pq3etsec_rxqueue { 138 1.2 matt bus_dmamap_t rxq_descmap; 139 1.2 matt volatile struct rxbd *rxq_consumer; 140 1.2 matt volatile struct rxbd *rxq_producer; 141 1.2 matt volatile struct rxbd *rxq_first; 142 1.2 matt volatile struct rxbd *rxq_last; 143 1.2 matt struct mbuf *rxq_mhead; 144 1.2 matt struct mbuf **rxq_mtail; 145 1.2 matt struct mbuf *rxq_mconsumer; 146 1.2 matt #ifdef ETSEC_DEBUG 147 1.2 matt struct mbuf *rxq_mbufs[512]; 148 1.2 matt #endif 149 1.2 matt uint32_t rxq_qmask; 150 1.2 matt uint32_t rxq_inuse; 151 1.2 matt uint32_t rxq_threshold; 152 1.2 matt bus_size_t rxq_reg_rbase; 153 1.2 matt bus_size_t rxq_reg_rbptr; 154 1.2 matt bus_dma_segment_t rxq_descmap_seg; 155 1.2 matt }; 156 1.2 matt 157 1.2 matt struct pq3etsec_mapcache { 158 1.2 matt u_int dmc_nmaps; 159 1.2 matt u_int dmc_maxseg; 160 1.2 matt u_int dmc_maxmaps; 161 1.2 matt u_int dmc_maxmapsize; 162 1.2 matt bus_dmamap_t dmc_maps[0]; 163 1.2 matt }; 164 1.2 matt 165 1.2 matt struct pq3etsec_softc { 166 1.2 matt device_t sc_dev; 167 1.16 matt device_t sc_mdio_dev; 168 1.2 matt struct ethercom sc_ec; 169 1.2 matt #define sc_if sc_ec.ec_if 170 1.2 matt struct mii_data sc_mii; 171 1.2 matt bus_space_tag_t sc_bst; 172 1.2 matt bus_space_handle_t sc_bsh; 173 1.15 matt bus_space_handle_t sc_mdio_bsh; 174 1.2 matt bus_dma_tag_t sc_dmat; 175 1.2 matt int sc_phy_addr; 176 1.2 matt prop_dictionary_t sc_intrmap; 177 1.2 matt uint32_t sc_intrmask; 178 1.2 matt 179 1.2 matt uint32_t sc_soft_flags; 180 1.2 matt #define SOFT_RESET 0x0001 181 1.2 matt #define SOFT_RXINTR 0x0010 182 1.2 matt #define SOFT_RXBSY 0x0020 183 1.2 matt #define SOFT_TXINTR 0x0100 184 1.2 matt #define SOFT_TXERROR 0x0200 185 1.2 matt 186 1.2 matt struct pq3etsec_txqueue sc_txq; 187 1.2 matt struct pq3etsec_rxqueue sc_rxq; 188 1.2 matt uint32_t sc_txerrors; 189 1.2 matt uint32_t sc_rxerrors; 190 1.2 matt 191 1.2 matt size_t sc_rx_adjlen; 192 1.2 matt 193 1.2 matt /* 194 1.2 matt * Copies of various ETSEC registers. 195 1.2 matt */ 196 1.2 matt uint32_t sc_imask; 197 1.2 matt uint32_t sc_maccfg1; 198 1.2 matt uint32_t sc_maccfg2; 199 1.2 matt uint32_t sc_maxfrm; 200 1.2 matt uint32_t sc_ecntrl; 201 1.2 matt uint32_t sc_dmactrl; 202 1.2 matt uint32_t sc_macstnaddr1; 203 1.2 matt uint32_t sc_macstnaddr2; 204 1.2 matt uint32_t sc_tctrl; 205 1.2 matt uint32_t sc_rctrl; 206 1.2 matt uint32_t sc_gaddr[16]; 207 1.2 matt uint64_t sc_macaddrs[15]; 208 1.2 matt 209 1.2 matt void *sc_tx_ih; 210 1.2 matt void *sc_rx_ih; 211 1.2 matt void *sc_error_ih; 212 1.2 matt void *sc_soft_ih; 213 1.2 matt 214 1.2 matt kmutex_t *sc_lock; 215 1.2 matt 216 1.2 matt struct evcnt sc_ev_tx_stall; 217 1.2 matt struct evcnt sc_ev_tx_intr; 218 1.2 matt struct evcnt sc_ev_rx_stall; 219 1.2 matt struct evcnt sc_ev_rx_intr; 220 1.2 matt struct evcnt sc_ev_error_intr; 221 1.2 matt struct evcnt sc_ev_soft_intr; 222 1.2 matt struct evcnt sc_ev_tx_pause; 223 1.2 matt struct evcnt sc_ev_rx_pause; 224 1.2 matt struct evcnt sc_ev_mii_ticks; 225 1.2 matt 226 1.2 matt struct callout sc_mii_callout; 227 1.2 matt uint64_t sc_mii_last_tick; 228 1.2 matt 229 1.2 matt struct ifqueue sc_rx_bufcache; 230 1.2 matt struct pq3etsec_mapcache *sc_rx_mapcache; 231 1.2 matt struct pq3etsec_mapcache *sc_tx_mapcache; 232 1.2 matt }; 233 1.2 matt 234 1.16 matt struct pq3mdio_softc { 235 1.16 matt device_t mdio_dev; 236 1.16 matt 237 1.16 matt kmutex_t *mdio_lock; 238 1.16 matt 239 1.16 matt bus_space_tag_t mdio_bst; 240 1.16 matt bus_space_handle_t mdio_bsh; 241 1.16 matt }; 242 1.16 matt 243 1.2 matt static int pq3etsec_match(device_t, cfdata_t, void *); 244 1.2 matt static void pq3etsec_attach(device_t, device_t, void *); 245 1.2 matt 246 1.16 matt static int pq3mdio_match(device_t, cfdata_t, void *); 247 1.16 matt static void pq3mdio_attach(device_t, device_t, void *); 248 1.16 matt 249 1.2 matt static void pq3etsec_ifstart(struct ifnet *); 250 1.2 matt static void pq3etsec_ifwatchdog(struct ifnet *); 251 1.2 matt static int pq3etsec_ifinit(struct ifnet *); 252 1.2 matt static void pq3etsec_ifstop(struct ifnet *, int); 253 1.2 matt static int pq3etsec_ifioctl(struct ifnet *, u_long, void *); 254 1.2 matt 255 1.2 matt static int pq3etsec_mapcache_create(struct pq3etsec_softc *, 256 1.10 matt struct pq3etsec_mapcache **, size_t, size_t, size_t); 257 1.2 matt static void pq3etsec_mapcache_destroy(struct pq3etsec_softc *, 258 1.2 matt struct pq3etsec_mapcache *); 259 1.2 matt static bus_dmamap_t pq3etsec_mapcache_get(struct pq3etsec_softc *, 260 1.2 matt struct pq3etsec_mapcache *); 261 1.2 matt static void pq3etsec_mapcache_put(struct pq3etsec_softc *, 262 1.2 matt struct pq3etsec_mapcache *, bus_dmamap_t); 263 1.2 matt 264 1.2 matt static int pq3etsec_txq_attach(struct pq3etsec_softc *, 265 1.2 matt struct pq3etsec_txqueue *, u_int); 266 1.2 matt static void pq3etsec_txq_purge(struct pq3etsec_softc *, 267 1.2 matt struct pq3etsec_txqueue *); 268 1.2 matt static void pq3etsec_txq_reset(struct pq3etsec_softc *, 269 1.2 matt struct pq3etsec_txqueue *); 270 1.2 matt static bool pq3etsec_txq_consume(struct pq3etsec_softc *, 271 1.2 matt struct pq3etsec_txqueue *); 272 1.2 matt static bool pq3etsec_txq_produce(struct pq3etsec_softc *, 273 1.2 matt struct pq3etsec_txqueue *, struct mbuf *m); 274 1.2 matt static bool pq3etsec_txq_active_p(struct pq3etsec_softc *, 275 1.2 matt struct pq3etsec_txqueue *); 276 1.2 matt 277 1.2 matt static int pq3etsec_rxq_attach(struct pq3etsec_softc *, 278 1.2 matt struct pq3etsec_rxqueue *, u_int); 279 1.2 matt static bool pq3etsec_rxq_produce(struct pq3etsec_softc *, 280 1.2 matt struct pq3etsec_rxqueue *); 281 1.2 matt static void pq3etsec_rxq_purge(struct pq3etsec_softc *, 282 1.2 matt struct pq3etsec_rxqueue *, bool); 283 1.2 matt static void pq3etsec_rxq_reset(struct pq3etsec_softc *, 284 1.2 matt struct pq3etsec_rxqueue *); 285 1.2 matt 286 1.2 matt static void pq3etsec_mc_setup(struct pq3etsec_softc *); 287 1.2 matt 288 1.2 matt static void pq3etsec_mii_tick(void *); 289 1.2 matt static int pq3etsec_rx_intr(void *); 290 1.2 matt static int pq3etsec_tx_intr(void *); 291 1.2 matt static int pq3etsec_error_intr(void *); 292 1.2 matt static void pq3etsec_soft_intr(void *); 293 1.2 matt 294 1.2 matt CFATTACH_DECL_NEW(pq3etsec, sizeof(struct pq3etsec_softc), 295 1.2 matt pq3etsec_match, pq3etsec_attach, NULL, NULL); 296 1.2 matt 297 1.16 matt CFATTACH_DECL_NEW(pq3mdio_tsec, sizeof(struct pq3mdio_softc), 298 1.16 matt pq3mdio_match, pq3mdio_attach, NULL, NULL); 299 1.16 matt 300 1.16 matt CFATTACH_DECL_NEW(pq3mdio_cpunode, sizeof(struct pq3mdio_softc), 301 1.16 matt pq3mdio_match, pq3mdio_attach, NULL, NULL); 302 1.16 matt 303 1.16 matt static inline uint32_t 304 1.16 matt etsec_mdio_read(struct pq3mdio_softc *mdio, bus_size_t off) 305 1.2 matt { 306 1.16 matt return bus_space_read_4(mdio->mdio_bst, mdio->mdio_bsh, off); 307 1.16 matt } 308 1.2 matt 309 1.16 matt static inline void 310 1.16 matt etsec_mdio_write(struct pq3mdio_softc *mdio, bus_size_t off, uint32_t data) 311 1.16 matt { 312 1.16 matt bus_space_write_4(mdio->mdio_bst, mdio->mdio_bsh, off, data); 313 1.2 matt } 314 1.2 matt 315 1.2 matt static inline uint32_t 316 1.2 matt etsec_read(struct pq3etsec_softc *sc, bus_size_t off) 317 1.2 matt { 318 1.2 matt return bus_space_read_4(sc->sc_bst, sc->sc_bsh, off); 319 1.2 matt } 320 1.2 matt 321 1.16 matt static int 322 1.16 matt pq3mdio_find(device_t parent, cfdata_t cf, const int *ldesc, void *aux) 323 1.2 matt { 324 1.16 matt return strcmp(cf->cf_name, "mdio") == 0; 325 1.2 matt } 326 1.2 matt 327 1.16 matt static int 328 1.16 matt pq3mdio_match(device_t parent, cfdata_t cf, void *aux) 329 1.15 matt { 330 1.16 matt const uint16_t svr = (mfspr(SPR_SVR) & ~0x80000) >> 16; 331 1.16 matt const bool p1025_p = (svr == (SVR_P1025v1 >> 16) 332 1.16 matt || svr == (SVR_P1016v1 >> 16)); 333 1.16 matt 334 1.16 matt if (device_is_a(parent, "cpunode")) { 335 1.18 nonaka if (!p1025_p 336 1.16 matt || !e500_cpunode_submatch(parent, cf, cf->cf_name, aux)) 337 1.16 matt return 0; 338 1.16 matt 339 1.16 matt return 1; 340 1.16 matt } 341 1.16 matt 342 1.16 matt if (device_is_a(parent, "tsec")) { 343 1.18 nonaka if (p1025_p 344 1.16 matt || !e500_cpunode_submatch(parent, cf, cf->cf_name, aux)) 345 1.16 matt return 0; 346 1.16 matt 347 1.16 matt return 1; 348 1.16 matt } 349 1.16 matt 350 1.16 matt return 0; 351 1.15 matt } 352 1.15 matt 353 1.16 matt static void 354 1.16 matt pq3mdio_attach(device_t parent, device_t self, void *aux) 355 1.15 matt { 356 1.16 matt struct pq3mdio_softc * const mdio = device_private(self); 357 1.16 matt struct cpunode_attach_args * const cna = aux; 358 1.16 matt struct cpunode_locators * const cnl = &cna->cna_locs; 359 1.16 matt 360 1.16 matt mdio->mdio_dev = self; 361 1.16 matt mdio->mdio_lock = mutex_obj_alloc(MUTEX_DEFAULT, IPL_SOFTNET); 362 1.16 matt 363 1.16 matt if (device_is_a(parent, "cpunode")) { 364 1.16 matt struct cpunode_softc * const psc = device_private(parent); 365 1.16 matt psc->sc_children |= cna->cna_childmask; 366 1.16 matt 367 1.16 matt mdio->mdio_bst = cna->cna_memt; 368 1.16 matt if (bus_space_map(mdio->mdio_bst, cnl->cnl_addr, 369 1.16 matt cnl->cnl_size, 0, &mdio->mdio_bsh) != 0) { 370 1.16 matt aprint_error(": error mapping registers @ %#x\n", 371 1.16 matt cnl->cnl_addr); 372 1.16 matt return; 373 1.16 matt } 374 1.16 matt } else { 375 1.16 matt struct pq3etsec_softc * const sc = device_private(parent); 376 1.16 matt 377 1.16 matt KASSERT(device_is_a(parent, "tsec")); 378 1.16 matt KASSERTMSG(cnl->cnl_addr == ETSEC1_BASE 379 1.16 matt || cnl->cnl_addr == ETSEC2_BASE 380 1.16 matt || cnl->cnl_addr == ETSEC3_BASE 381 1.16 matt || cnl->cnl_addr == ETSEC4_BASE, 382 1.16 matt "unknown tsec addr %x", cnl->cnl_addr); 383 1.16 matt 384 1.16 matt mdio->mdio_bst = sc->sc_bst; 385 1.16 matt mdio->mdio_bsh = sc->sc_bsh; 386 1.16 matt } 387 1.16 matt 388 1.16 matt aprint_normal("\n"); 389 1.15 matt } 390 1.15 matt 391 1.2 matt static int 392 1.16 matt pq3mdio_mii_readreg(device_t self, int phy, int reg) 393 1.2 matt { 394 1.16 matt struct pq3mdio_softc * const mdio = device_private(self); 395 1.16 matt uint32_t miimcom = etsec_mdio_read(mdio, MIIMCOM); 396 1.2 matt 397 1.16 matt mutex_enter(mdio->mdio_lock); 398 1.2 matt 399 1.16 matt etsec_mdio_write(mdio, MIIMADD, 400 1.2 matt __SHIFTIN(phy, MIIMADD_PHY) | __SHIFTIN(reg, MIIMADD_REG)); 401 1.2 matt 402 1.16 matt etsec_mdio_write(mdio, MIIMCOM, 0); /* clear any past bits */ 403 1.16 matt etsec_mdio_write(mdio, MIIMCOM, MIIMCOM_READ); 404 1.2 matt 405 1.16 matt while (etsec_mdio_read(mdio, MIIMIND) != 0) { 406 1.2 matt delay(1); 407 1.2 matt } 408 1.16 matt int data = etsec_mdio_read(mdio, MIIMSTAT); 409 1.2 matt 410 1.2 matt if (miimcom == MIIMCOM_SCAN) 411 1.16 matt etsec_mdio_write(mdio, MIIMCOM, miimcom); 412 1.2 matt 413 1.2 matt #if 0 414 1.16 matt aprint_normal_dev(mdio->mdio_dev, "%s: phy %d reg %d: %#x\n", 415 1.2 matt __func__, phy, reg, data); 416 1.2 matt #endif 417 1.16 matt mutex_exit(mdio->mdio_lock); 418 1.2 matt return data; 419 1.2 matt } 420 1.2 matt 421 1.2 matt static void 422 1.16 matt pq3mdio_mii_writereg(device_t self, int phy, int reg, int data) 423 1.2 matt { 424 1.16 matt struct pq3mdio_softc * const mdio = device_private(self); 425 1.16 matt uint32_t miimcom = etsec_mdio_read(mdio, MIIMCOM); 426 1.2 matt 427 1.2 matt #if 0 428 1.16 matt aprint_normal_dev(mdio->mdio_dev, "%s: phy %d reg %d: %#x\n", 429 1.2 matt __func__, phy, reg, data); 430 1.2 matt #endif 431 1.2 matt 432 1.16 matt mutex_enter(mdio->mdio_lock); 433 1.16 matt 434 1.16 matt etsec_mdio_write(mdio, MIIMADD, 435 1.2 matt __SHIFTIN(phy, MIIMADD_PHY) | __SHIFTIN(reg, MIIMADD_REG)); 436 1.16 matt etsec_mdio_write(mdio, MIIMCOM, 0); /* clear any past bits */ 437 1.16 matt etsec_mdio_write(mdio, MIIMCON, data); 438 1.2 matt 439 1.2 matt int timo = 1000; /* 1ms */ 440 1.16 matt while ((etsec_mdio_read(mdio, MIIMIND) & MIIMIND_BUSY) && --timo > 0) { 441 1.2 matt delay(1); 442 1.2 matt } 443 1.2 matt 444 1.2 matt if (miimcom == MIIMCOM_SCAN) 445 1.16 matt etsec_mdio_write(mdio, MIIMCOM, miimcom); 446 1.16 matt 447 1.16 matt mutex_exit(mdio->mdio_lock); 448 1.16 matt } 449 1.16 matt 450 1.16 matt static inline void 451 1.16 matt etsec_write(struct pq3etsec_softc *sc, bus_size_t off, uint32_t data) 452 1.16 matt { 453 1.16 matt bus_space_write_4(sc->sc_bst, sc->sc_bsh, off, data); 454 1.2 matt } 455 1.2 matt 456 1.2 matt static void 457 1.16 matt pq3etsec_mii_statchg(struct ifnet *ifp) 458 1.2 matt { 459 1.16 matt struct pq3etsec_softc * const sc = ifp->if_softc; 460 1.2 matt struct mii_data * const mii = &sc->sc_mii; 461 1.2 matt 462 1.2 matt uint32_t maccfg1 = sc->sc_maccfg1; 463 1.2 matt uint32_t maccfg2 = sc->sc_maccfg2; 464 1.2 matt uint32_t ecntrl = sc->sc_ecntrl; 465 1.2 matt 466 1.2 matt maccfg1 &= ~(MACCFG1_TX_FLOW|MACCFG1_RX_FLOW); 467 1.2 matt maccfg2 &= ~(MACCFG2_IFMODE|MACCFG2_FD); 468 1.2 matt 469 1.2 matt if (sc->sc_mii.mii_media_active & IFM_FDX) { 470 1.2 matt maccfg2 |= MACCFG2_FD; 471 1.2 matt } 472 1.2 matt 473 1.2 matt /* 474 1.2 matt * Now deal with the flow control bits. 475 1.2 matt */ 476 1.2 matt if (IFM_SUBTYPE(mii->mii_media.ifm_cur->ifm_media) == IFM_AUTO 477 1.2 matt && (mii->mii_media_active & IFM_ETH_FMASK)) { 478 1.2 matt if (mii->mii_media_active & IFM_ETH_RXPAUSE) 479 1.2 matt maccfg1 |= MACCFG1_RX_FLOW; 480 1.2 matt if (mii->mii_media_active & IFM_ETH_TXPAUSE) 481 1.2 matt maccfg1 |= MACCFG1_TX_FLOW; 482 1.2 matt } 483 1.2 matt 484 1.2 matt /* 485 1.2 matt * Now deal with the speed. 486 1.2 matt */ 487 1.2 matt if (IFM_SUBTYPE(mii->mii_media_active) == IFM_1000_T) { 488 1.2 matt maccfg2 |= MACCFG2_IFMODE_GMII; 489 1.2 matt } else { 490 1.2 matt maccfg2 |= MACCFG2_IFMODE_MII; 491 1.2 matt ecntrl &= ~ECNTRL_R100M; 492 1.2 matt if (IFM_SUBTYPE(mii->mii_media_active) != IFM_10_T) { 493 1.2 matt ecntrl |= ECNTRL_R100M; 494 1.2 matt } 495 1.2 matt } 496 1.2 matt 497 1.2 matt /* 498 1.2 matt * If things are different, re-init things. 499 1.2 matt */ 500 1.2 matt if (maccfg1 != sc->sc_maccfg1 501 1.2 matt || maccfg2 != sc->sc_maccfg2 502 1.2 matt || ecntrl != sc->sc_ecntrl) { 503 1.2 matt if (sc->sc_if.if_flags & IFF_RUNNING) 504 1.2 matt atomic_or_uint(&sc->sc_soft_flags, SOFT_RESET); 505 1.2 matt sc->sc_maccfg1 = maccfg1; 506 1.2 matt sc->sc_maccfg2 = maccfg2; 507 1.2 matt sc->sc_ecntrl = ecntrl; 508 1.2 matt } 509 1.2 matt } 510 1.2 matt 511 1.2 matt #if 0 512 1.2 matt static void 513 1.2 matt pq3etsec_mediastatus(struct ifnet *ifp, struct ifmediareq *ifmr) 514 1.2 matt { 515 1.2 matt struct pq3etsec_softc * const sc = ifp->if_softc; 516 1.2 matt 517 1.2 matt mii_pollstat(&sc->sc_mii); 518 1.2 matt ether_mediastatus(ifp, ifmr); 519 1.2 matt ifmr->ifm_status = sc->sc_mii.mii_media_status; 520 1.2 matt ifmr->ifm_active = sc->sc_mii.mii_media_active; 521 1.2 matt } 522 1.2 matt 523 1.2 matt static int 524 1.2 matt pq3etsec_mediachange(struct ifnet *ifp) 525 1.2 matt { 526 1.2 matt struct pq3etsec_softc * const sc = ifp->if_softc; 527 1.2 matt 528 1.2 matt if ((ifp->if_flags & IFF_UP) == 0) 529 1.2 matt return 0; 530 1.2 matt 531 1.2 matt int rv = mii_mediachg(&sc->sc_mii); 532 1.2 matt return (rv == ENXIO) ? 0 : rv; 533 1.2 matt } 534 1.2 matt #endif 535 1.2 matt 536 1.16 matt static int 537 1.16 matt pq3etsec_match(device_t parent, cfdata_t cf, void *aux) 538 1.16 matt { 539 1.15 matt 540 1.16 matt if (!e500_cpunode_submatch(parent, cf, cf->cf_name, aux)) 541 1.16 matt return 0; 542 1.15 matt 543 1.16 matt return 1; 544 1.15 matt } 545 1.15 matt 546 1.2 matt static void 547 1.2 matt pq3etsec_attach(device_t parent, device_t self, void *aux) 548 1.2 matt { 549 1.2 matt struct cpunode_softc * const psc = device_private(parent); 550 1.2 matt struct pq3etsec_softc * const sc = device_private(self); 551 1.2 matt struct cpunode_attach_args * const cna = aux; 552 1.2 matt struct cpunode_locators * const cnl = &cna->cna_locs; 553 1.5 matt cfdata_t cf = device_cfdata(self); 554 1.2 matt int error; 555 1.2 matt 556 1.2 matt psc->sc_children |= cna->cna_childmask; 557 1.2 matt sc->sc_dev = self; 558 1.2 matt sc->sc_bst = cna->cna_memt; 559 1.2 matt sc->sc_dmat = &booke_bus_dma_tag; 560 1.2 matt 561 1.2 matt /* 562 1.16 matt * Pull out the mdio bus and phy we are supposed to use. 563 1.2 matt */ 564 1.16 matt const int mdio = cf->cf_loc[CPUNODECF_MDIO]; 565 1.16 matt const int phy = cf->cf_loc[CPUNODECF_PHY]; 566 1.16 matt if (mdio != CPUNODECF_MDIO_DEFAULT) 567 1.16 matt aprint_normal(" mdio %d", mdio); 568 1.2 matt 569 1.2 matt /* 570 1.2 matt * See if the phy is in the config file... 571 1.2 matt */ 572 1.16 matt if (phy != CPUNODECF_PHY_DEFAULT) { 573 1.16 matt sc->sc_phy_addr = phy; 574 1.2 matt } else { 575 1.2 matt unsigned char prop_name[20]; 576 1.2 matt snprintf(prop_name, sizeof(prop_name), "tsec%u-phy-addr", 577 1.2 matt cnl->cnl_instance); 578 1.2 matt sc->sc_phy_addr = board_info_get_number(prop_name); 579 1.2 matt } 580 1.9 matt if (sc->sc_phy_addr != MII_PHY_ANY) 581 1.9 matt aprint_normal(" phy %d", sc->sc_phy_addr); 582 1.2 matt 583 1.2 matt error = bus_space_map(sc->sc_bst, cnl->cnl_addr, cnl->cnl_size, 0, 584 1.2 matt &sc->sc_bsh); 585 1.2 matt if (error) { 586 1.2 matt aprint_error(": error mapping registers: %d\n", error); 587 1.2 matt return; 588 1.2 matt } 589 1.2 matt 590 1.2 matt /* 591 1.2 matt * Assume firmware has aready set the mac address and fetch it 592 1.2 matt * before we reinit it. 593 1.2 matt */ 594 1.2 matt sc->sc_macstnaddr2 = etsec_read(sc, MACSTNADDR2); 595 1.2 matt sc->sc_macstnaddr1 = etsec_read(sc, MACSTNADDR1); 596 1.2 matt sc->sc_rctrl = RCTRL_DEFAULT; 597 1.12 matt sc->sc_ecntrl = etsec_read(sc, ECNTRL); 598 1.12 matt sc->sc_maccfg1 = etsec_read(sc, MACCFG1); 599 1.13 matt sc->sc_maccfg2 = etsec_read(sc, MACCFG2) | MACCFG2_DEFAULT; 600 1.2 matt 601 1.2 matt if (sc->sc_macstnaddr1 == 0 && sc->sc_macstnaddr2 == 0) { 602 1.2 matt size_t len; 603 1.2 matt const uint8_t *mac_addr = 604 1.2 matt board_info_get_data("tsec-mac-addr-base", &len); 605 1.2 matt KASSERT(len == ETHER_ADDR_LEN); 606 1.2 matt sc->sc_macstnaddr2 = 607 1.2 matt (mac_addr[1] << 24) 608 1.2 matt | (mac_addr[0] << 16); 609 1.2 matt sc->sc_macstnaddr1 = 610 1.2 matt ((mac_addr[5] + cnl->cnl_instance - 1) << 24) 611 1.2 matt | (mac_addr[4] << 16) 612 1.2 matt | (mac_addr[3] << 8) 613 1.2 matt | (mac_addr[2] << 0); 614 1.2 matt #if 0 615 1.2 matt aprint_error(": mac-address unknown\n"); 616 1.2 matt return; 617 1.2 matt #endif 618 1.2 matt } 619 1.2 matt 620 1.2 matt char enaddr[ETHER_ADDR_LEN] = { 621 1.2 matt [0] = sc->sc_macstnaddr2 >> 16, 622 1.2 matt [1] = sc->sc_macstnaddr2 >> 24, 623 1.2 matt [2] = sc->sc_macstnaddr1 >> 0, 624 1.2 matt [3] = sc->sc_macstnaddr1 >> 8, 625 1.2 matt [4] = sc->sc_macstnaddr1 >> 16, 626 1.2 matt [5] = sc->sc_macstnaddr1 >> 24, 627 1.2 matt }; 628 1.2 matt 629 1.2 matt error = pq3etsec_rxq_attach(sc, &sc->sc_rxq, 0); 630 1.2 matt if (error) { 631 1.2 matt aprint_error(": failed to init rxq: %d\n", error); 632 1.2 matt return; 633 1.2 matt } 634 1.2 matt 635 1.2 matt error = pq3etsec_txq_attach(sc, &sc->sc_txq, 0); 636 1.2 matt if (error) { 637 1.2 matt aprint_error(": failed to init txq: %d\n", error); 638 1.2 matt return; 639 1.2 matt } 640 1.2 matt 641 1.2 matt error = pq3etsec_mapcache_create(sc, &sc->sc_rx_mapcache, 642 1.10 matt ETSEC_MAXRXMBUFS, MCLBYTES, ETSEC_NRXSEGS); 643 1.2 matt if (error) { 644 1.2 matt aprint_error(": failed to allocate rx dmamaps: %d\n", error); 645 1.2 matt return; 646 1.2 matt } 647 1.2 matt 648 1.2 matt error = pq3etsec_mapcache_create(sc, &sc->sc_tx_mapcache, 649 1.10 matt ETSEC_MAXTXMBUFS, MCLBYTES, ETSEC_NTXSEGS); 650 1.2 matt if (error) { 651 1.2 matt aprint_error(": failed to allocate tx dmamaps: %d\n", error); 652 1.2 matt return; 653 1.2 matt } 654 1.2 matt 655 1.2 matt sc->sc_tx_ih = intr_establish(cnl->cnl_intrs[0], IPL_VM, IST_ONCHIP, 656 1.2 matt pq3etsec_tx_intr, sc); 657 1.2 matt if (sc->sc_tx_ih == NULL) { 658 1.2 matt aprint_error(": failed to establish tx interrupt: %d\n", 659 1.2 matt cnl->cnl_intrs[0]); 660 1.2 matt return; 661 1.2 matt } 662 1.2 matt 663 1.2 matt sc->sc_rx_ih = intr_establish(cnl->cnl_intrs[1], IPL_VM, IST_ONCHIP, 664 1.2 matt pq3etsec_rx_intr, sc); 665 1.2 matt if (sc->sc_rx_ih == NULL) { 666 1.2 matt aprint_error(": failed to establish rx interrupt: %d\n", 667 1.2 matt cnl->cnl_intrs[1]); 668 1.2 matt return; 669 1.2 matt } 670 1.2 matt 671 1.2 matt sc->sc_error_ih = intr_establish(cnl->cnl_intrs[2], IPL_VM, IST_ONCHIP, 672 1.2 matt pq3etsec_error_intr, sc); 673 1.2 matt if (sc->sc_error_ih == NULL) { 674 1.2 matt aprint_error(": failed to establish error interrupt: %d\n", 675 1.2 matt cnl->cnl_intrs[2]); 676 1.2 matt return; 677 1.2 matt } 678 1.2 matt 679 1.2 matt sc->sc_soft_ih = softint_establish(SOFTINT_NET|SOFTINT_MPSAFE, 680 1.2 matt pq3etsec_soft_intr, sc); 681 1.2 matt if (sc->sc_soft_ih == NULL) { 682 1.2 matt aprint_error(": failed to establish soft interrupt\n"); 683 1.2 matt return; 684 1.2 matt } 685 1.2 matt 686 1.16 matt /* 687 1.19 nonaka * If there was no MDIO 688 1.16 matt */ 689 1.16 matt if (mdio == CPUNODECF_MDIO_DEFAULT) { 690 1.16 matt aprint_normal("\n"); 691 1.16 matt cfdata_t mdio_cf = config_search_ia(pq3mdio_find, self, NULL, cna); 692 1.16 matt if (mdio_cf != NULL) { 693 1.16 matt sc->sc_mdio_dev = config_attach(self, mdio_cf, cna, NULL); 694 1.16 matt } 695 1.16 matt } else { 696 1.16 matt sc->sc_mdio_dev = device_find_by_driver_unit("mdio", mdio); 697 1.16 matt if (sc->sc_mdio_dev == NULL) { 698 1.16 matt aprint_error(": failed to locate mdio device\n"); 699 1.16 matt return; 700 1.16 matt } 701 1.16 matt aprint_normal("\n"); 702 1.16 matt } 703 1.2 matt 704 1.4 matt etsec_write(sc, ATTR, ATTR_DEFAULT); 705 1.4 matt etsec_write(sc, ATTRELI, ATTRELI_DEFAULT); 706 1.4 matt 707 1.2 matt sc->sc_lock = mutex_obj_alloc(MUTEX_DEFAULT, IPL_SOFTNET); 708 1.2 matt 709 1.2 matt callout_init(&sc->sc_mii_callout, CALLOUT_MPSAFE); 710 1.2 matt callout_setfunc(&sc->sc_mii_callout, pq3etsec_mii_tick, sc); 711 1.2 matt 712 1.2 matt aprint_normal_dev(sc->sc_dev, "Ethernet address %s\n", 713 1.2 matt ether_sprintf(enaddr)); 714 1.2 matt 715 1.2 matt const char * const xname = device_xname(sc->sc_dev); 716 1.2 matt struct ethercom * const ec = &sc->sc_ec; 717 1.2 matt struct ifnet * const ifp = &ec->ec_if; 718 1.2 matt 719 1.2 matt ec->ec_mii = &sc->sc_mii; 720 1.2 matt 721 1.2 matt sc->sc_mii.mii_ifp = ifp; 722 1.16 matt sc->sc_mii.mii_readreg = pq3mdio_mii_readreg; 723 1.16 matt sc->sc_mii.mii_writereg = pq3mdio_mii_writereg; 724 1.2 matt sc->sc_mii.mii_statchg = pq3etsec_mii_statchg; 725 1.2 matt 726 1.2 matt ifmedia_init(&sc->sc_mii.mii_media, 0, ether_mediachange, 727 1.2 matt ether_mediastatus); 728 1.2 matt 729 1.16 matt if (sc->sc_mdio_dev != NULL && sc->sc_phy_addr < 32) { 730 1.16 matt mii_attach(sc->sc_mdio_dev, &sc->sc_mii, 0xffffffff, 731 1.3 matt sc->sc_phy_addr, MII_OFFSET_ANY, MIIF_DOPAUSE); 732 1.3 matt 733 1.3 matt if (LIST_FIRST(&sc->sc_mii.mii_phys) == NULL) { 734 1.3 matt ifmedia_add(&sc->sc_mii.mii_media, IFM_ETHER|IFM_NONE, 0, NULL); 735 1.3 matt ifmedia_set(&sc->sc_mii.mii_media, IFM_ETHER|IFM_NONE); 736 1.3 matt } else { 737 1.3 matt callout_schedule(&sc->sc_mii_callout, hz); 738 1.3 matt ifmedia_set(&sc->sc_mii.mii_media, IFM_ETHER|IFM_AUTO); 739 1.3 matt } 740 1.2 matt } else { 741 1.3 matt ifmedia_add(&sc->sc_mii.mii_media, IFM_ETHER|IFM_1000_T|IFM_FDX, 0, NULL); 742 1.3 matt ifmedia_set(&sc->sc_mii.mii_media, IFM_ETHER|IFM_1000_T|IFM_FDX); 743 1.2 matt } 744 1.2 matt 745 1.2 matt ec->ec_capabilities = ETHERCAP_VLAN_MTU | ETHERCAP_VLAN_HWTAGGING 746 1.2 matt | ETHERCAP_JUMBO_MTU; 747 1.2 matt 748 1.2 matt strlcpy(ifp->if_xname, xname, IFNAMSIZ); 749 1.2 matt ifp->if_softc = sc; 750 1.2 matt ifp->if_capabilities = IFCAP_ETSEC; 751 1.2 matt ifp->if_flags = IFF_BROADCAST | IFF_SIMPLEX | IFF_MULTICAST; 752 1.2 matt ifp->if_ioctl = pq3etsec_ifioctl; 753 1.2 matt ifp->if_start = pq3etsec_ifstart; 754 1.2 matt ifp->if_watchdog = pq3etsec_ifwatchdog; 755 1.2 matt ifp->if_init = pq3etsec_ifinit; 756 1.2 matt ifp->if_stop = pq3etsec_ifstop; 757 1.2 matt IFQ_SET_READY(&ifp->if_snd); 758 1.2 matt 759 1.2 matt pq3etsec_ifstop(ifp, true); 760 1.2 matt 761 1.2 matt /* 762 1.2 matt * Attach the interface. 763 1.2 matt */ 764 1.21 nonaka if_initialize(ifp); 765 1.2 matt ether_ifattach(ifp, enaddr); 766 1.21 nonaka if_register(ifp); 767 1.2 matt 768 1.2 matt evcnt_attach_dynamic(&sc->sc_ev_rx_stall, EVCNT_TYPE_MISC, 769 1.2 matt NULL, xname, "rx stall"); 770 1.2 matt evcnt_attach_dynamic(&sc->sc_ev_tx_stall, EVCNT_TYPE_MISC, 771 1.2 matt NULL, xname, "tx stall"); 772 1.2 matt evcnt_attach_dynamic(&sc->sc_ev_tx_intr, EVCNT_TYPE_INTR, 773 1.2 matt NULL, xname, "tx intr"); 774 1.2 matt evcnt_attach_dynamic(&sc->sc_ev_rx_intr, EVCNT_TYPE_INTR, 775 1.2 matt NULL, xname, "rx intr"); 776 1.2 matt evcnt_attach_dynamic(&sc->sc_ev_error_intr, EVCNT_TYPE_INTR, 777 1.2 matt NULL, xname, "error intr"); 778 1.2 matt evcnt_attach_dynamic(&sc->sc_ev_soft_intr, EVCNT_TYPE_INTR, 779 1.2 matt NULL, xname, "soft intr"); 780 1.2 matt evcnt_attach_dynamic(&sc->sc_ev_tx_pause, EVCNT_TYPE_MISC, 781 1.2 matt NULL, xname, "tx pause"); 782 1.2 matt evcnt_attach_dynamic(&sc->sc_ev_rx_pause, EVCNT_TYPE_MISC, 783 1.2 matt NULL, xname, "rx pause"); 784 1.2 matt evcnt_attach_dynamic(&sc->sc_ev_mii_ticks, EVCNT_TYPE_MISC, 785 1.2 matt NULL, xname, "mii ticks"); 786 1.2 matt } 787 1.2 matt 788 1.2 matt static uint64_t 789 1.2 matt pq3etsec_macaddr_create(const uint8_t *lladdr) 790 1.2 matt { 791 1.2 matt uint64_t macaddr = 0; 792 1.2 matt 793 1.2 matt lladdr += ETHER_ADDR_LEN; 794 1.2 matt for (u_int i = ETHER_ADDR_LEN; i-- > 0; ) { 795 1.2 matt macaddr = (macaddr << 8) | *--lladdr; 796 1.2 matt } 797 1.2 matt return macaddr << 16; 798 1.2 matt } 799 1.2 matt 800 1.2 matt static int 801 1.2 matt pq3etsec_ifinit(struct ifnet *ifp) 802 1.2 matt { 803 1.2 matt struct pq3etsec_softc * const sc = ifp->if_softc; 804 1.2 matt int error = 0; 805 1.2 matt 806 1.2 matt sc->sc_maxfrm = max(ifp->if_mtu + 32, MCLBYTES); 807 1.2 matt if (ifp->if_mtu > ETHERMTU_JUMBO) 808 1.2 matt return error; 809 1.2 matt 810 1.2 matt KASSERT(ifp->if_flags & IFF_UP); 811 1.2 matt 812 1.2 matt /* 813 1.2 matt * Stop the interface (steps 1 to 4 in the Soft Reset and 814 1.2 matt * Reconfigurating Procedure. 815 1.2 matt */ 816 1.2 matt pq3etsec_ifstop(ifp, 0); 817 1.2 matt 818 1.2 matt /* 819 1.2 matt * If our frame size has changed (or it's our first time through) 820 1.2 matt * destroy the existing transmit mapcache. 821 1.2 matt */ 822 1.2 matt if (sc->sc_tx_mapcache != NULL 823 1.2 matt && sc->sc_maxfrm != sc->sc_tx_mapcache->dmc_maxmapsize) { 824 1.2 matt pq3etsec_mapcache_destroy(sc, sc->sc_tx_mapcache); 825 1.2 matt sc->sc_tx_mapcache = NULL; 826 1.2 matt } 827 1.2 matt 828 1.2 matt if (sc->sc_tx_mapcache == NULL) { 829 1.2 matt error = pq3etsec_mapcache_create(sc, &sc->sc_tx_mapcache, 830 1.10 matt ETSEC_MAXTXMBUFS, sc->sc_maxfrm, ETSEC_NTXSEGS); 831 1.2 matt if (error) 832 1.2 matt return error; 833 1.2 matt } 834 1.2 matt 835 1.2 matt sc->sc_ev_mii_ticks.ev_count++; 836 1.2 matt mii_tick(&sc->sc_mii); 837 1.2 matt 838 1.2 matt if (ifp->if_flags & IFF_PROMISC) { 839 1.2 matt sc->sc_rctrl |= RCTRL_PROM; 840 1.2 matt } else { 841 1.2 matt sc->sc_rctrl &= ~RCTRL_PROM; 842 1.2 matt } 843 1.2 matt 844 1.2 matt uint32_t rctrl_prsdep = 0; 845 1.2 matt sc->sc_rctrl &= ~(RCTRL_IPCSEN|RCTRL_TUCSEN|RCTRL_VLEX|RCTRL_PRSDEP); 846 1.2 matt if (VLAN_ATTACHED(&sc->sc_ec)) { 847 1.2 matt sc->sc_rctrl |= RCTRL_VLEX; 848 1.2 matt rctrl_prsdep = RCTRL_PRSDEP_L2; 849 1.2 matt } 850 1.2 matt if (ifp->if_capenable & IFCAP_RCTRL_IPCSEN) { 851 1.2 matt sc->sc_rctrl |= RCTRL_IPCSEN; 852 1.2 matt rctrl_prsdep = RCTRL_PRSDEP_L3; 853 1.2 matt } 854 1.2 matt if (ifp->if_capenable & IFCAP_RCTRL_TUCSEN) { 855 1.2 matt sc->sc_rctrl |= RCTRL_TUCSEN; 856 1.2 matt rctrl_prsdep = RCTRL_PRSDEP_L4; 857 1.2 matt } 858 1.2 matt sc->sc_rctrl |= rctrl_prsdep; 859 1.2 matt #if 0 860 1.2 matt if (sc->sc_rctrl & (RCTRL_IPCSEN|RCTRL_TUCSEN|RCTRL_VLEX|RCTRL_PRSDEP)) 861 1.2 matt aprint_normal_dev(sc->sc_dev, 862 1.2 matt "rctrl=%#x ipcsen=%"PRIuMAX" tucsen=%"PRIuMAX" vlex=%"PRIuMAX" prsdep=%"PRIuMAX"\n", 863 1.2 matt sc->sc_rctrl, 864 1.2 matt __SHIFTOUT(sc->sc_rctrl, RCTRL_IPCSEN), 865 1.2 matt __SHIFTOUT(sc->sc_rctrl, RCTRL_TUCSEN), 866 1.2 matt __SHIFTOUT(sc->sc_rctrl, RCTRL_VLEX), 867 1.2 matt __SHIFTOUT(sc->sc_rctrl, RCTRL_PRSDEP)); 868 1.2 matt #endif 869 1.2 matt 870 1.2 matt sc->sc_tctrl &= ~(TCTRL_IPCSEN|TCTRL_TUCSEN|TCTRL_VLINS); 871 1.2 matt if (VLAN_ATTACHED(&sc->sc_ec)) /* is this really true */ 872 1.2 matt sc->sc_tctrl |= TCTRL_VLINS; 873 1.2 matt if (ifp->if_capenable & IFCAP_TCTRL_IPCSEN) 874 1.2 matt sc->sc_tctrl |= TCTRL_IPCSEN; 875 1.2 matt if (ifp->if_capenable & IFCAP_TCTRL_TUCSEN) 876 1.2 matt sc->sc_tctrl |= TCTRL_TUCSEN; 877 1.2 matt #if 0 878 1.2 matt if (sc->sc_tctrl & (TCTRL_IPCSEN|TCTRL_TUCSEN|TCTRL_VLINS)) 879 1.2 matt aprint_normal_dev(sc->sc_dev, 880 1.2 matt "tctrl=%#x ipcsen=%"PRIuMAX" tucsen=%"PRIuMAX" vlins=%"PRIuMAX"\n", 881 1.2 matt sc->sc_tctrl, 882 1.2 matt __SHIFTOUT(sc->sc_tctrl, TCTRL_IPCSEN), 883 1.2 matt __SHIFTOUT(sc->sc_tctrl, TCTRL_TUCSEN), 884 1.2 matt __SHIFTOUT(sc->sc_tctrl, TCTRL_VLINS)); 885 1.2 matt #endif 886 1.2 matt 887 1.2 matt sc->sc_maccfg1 &= ~(MACCFG1_TX_EN|MACCFG1_RX_EN); 888 1.2 matt 889 1.2 matt const uint64_t macstnaddr = 890 1.2 matt pq3etsec_macaddr_create(CLLADDR(ifp->if_sadl)); 891 1.2 matt 892 1.2 matt sc->sc_imask = IEVENT_DPE; 893 1.2 matt 894 1.2 matt /* 5. Load TDBPH, TBASEH, TBASE0-TBASE7 with new Tx BD pointers */ 895 1.2 matt pq3etsec_rxq_reset(sc, &sc->sc_rxq); 896 1.2 matt pq3etsec_rxq_produce(sc, &sc->sc_rxq); /* fill with rx buffers */ 897 1.2 matt 898 1.2 matt /* 6. Load RDBPH, RBASEH, RBASE0-RBASE7 with new Rx BD pointers */ 899 1.2 matt pq3etsec_txq_reset(sc, &sc->sc_txq); 900 1.2 matt 901 1.2 matt /* 7. Setup other MAC registers (MACCFG2, MAXFRM, etc.) */ 902 1.2 matt KASSERT(MACCFG2_PADCRC & sc->sc_maccfg2); 903 1.2 matt etsec_write(sc, MAXFRM, sc->sc_maxfrm); 904 1.2 matt etsec_write(sc, MACSTNADDR1, (uint32_t)(macstnaddr >> 32)); 905 1.2 matt etsec_write(sc, MACSTNADDR2, (uint32_t)(macstnaddr >> 0)); 906 1.2 matt etsec_write(sc, MACCFG1, sc->sc_maccfg1); 907 1.2 matt etsec_write(sc, MACCFG2, sc->sc_maccfg2); 908 1.2 matt etsec_write(sc, ECNTRL, sc->sc_ecntrl); 909 1.2 matt 910 1.2 matt /* 8. Setup group address hash table (GADDR0-GADDR15) */ 911 1.2 matt pq3etsec_mc_setup(sc); 912 1.2 matt 913 1.2 matt /* 9. Setup receive frame filer table (via RQFAR, RQFCR, and RQFPR) */ 914 1.2 matt etsec_write(sc, MRBLR, MCLBYTES); 915 1.2 matt 916 1.2 matt /* 10. Setup WWR, WOP, TOD bits in DMACTRL register */ 917 1.2 matt sc->sc_dmactrl |= DMACTRL_DEFAULT; 918 1.2 matt etsec_write(sc, DMACTRL, sc->sc_dmactrl); 919 1.2 matt 920 1.2 matt /* 11. Enable transmit queues in TQUEUE, and ensure that the transmit scheduling mode is correctly set in TCTRL. */ 921 1.2 matt etsec_write(sc, TQUEUE, TQUEUE_EN0); 922 1.2 matt sc->sc_imask |= IEVENT_TXF|IEVENT_TXE|IEVENT_TXC; 923 1.2 matt 924 1.2 matt etsec_write(sc, TCTRL, sc->sc_tctrl); /* for TOE stuff */ 925 1.2 matt 926 1.2 matt /* 12. Enable receive queues in RQUEUE, */ 927 1.2 matt etsec_write(sc, RQUEUE, RQUEUE_EN0|RQUEUE_EX0); 928 1.2 matt sc->sc_imask |= IEVENT_RXF|IEVENT_BSY|IEVENT_RXC; 929 1.2 matt 930 1.2 matt /* and optionally set TOE functionality in RCTRL. */ 931 1.2 matt etsec_write(sc, RCTRL, sc->sc_rctrl); 932 1.2 matt sc->sc_rx_adjlen = __SHIFTOUT(sc->sc_rctrl, RCTRL_PAL); 933 1.2 matt if ((sc->sc_rctrl & RCTRL_PRSDEP) != RCTRL_PRSDEP_OFF) 934 1.2 matt sc->sc_rx_adjlen += sizeof(struct rxfcb); 935 1.2 matt 936 1.2 matt /* 13. Clear THLT and TXF bits in TSTAT register by writing 1 to them */ 937 1.2 matt etsec_write(sc, TSTAT, TSTAT_THLT | TSTAT_TXF); 938 1.2 matt 939 1.2 matt /* 14. Clear QHLT and RXF bits in RSTAT register by writing 1 to them.*/ 940 1.2 matt etsec_write(sc, RSTAT, RSTAT_QHLT | RSTAT_RXF); 941 1.2 matt 942 1.2 matt /* 15. Clear GRS/GTS bits in DMACTRL (do not change other bits) */ 943 1.2 matt sc->sc_dmactrl &= ~(DMACTRL_GRS|DMACTRL_GTS); 944 1.2 matt etsec_write(sc, DMACTRL, sc->sc_dmactrl); 945 1.2 matt 946 1.2 matt /* 16. Enable Tx_EN/Rx_EN in MACCFG1 register */ 947 1.2 matt etsec_write(sc, MACCFG1, sc->sc_maccfg1 | MACCFG1_TX_EN|MACCFG1_RX_EN); 948 1.2 matt etsec_write(sc, MACCFG1, sc->sc_maccfg1 | MACCFG1_TX_EN|MACCFG1_RX_EN); 949 1.2 matt 950 1.2 matt sc->sc_soft_flags = 0; 951 1.2 matt 952 1.2 matt etsec_write(sc, IMASK, sc->sc_imask); 953 1.2 matt 954 1.2 matt ifp->if_flags |= IFF_RUNNING; 955 1.2 matt 956 1.2 matt return error; 957 1.2 matt } 958 1.2 matt 959 1.2 matt static void 960 1.2 matt pq3etsec_ifstop(struct ifnet *ifp, int disable) 961 1.2 matt { 962 1.2 matt struct pq3etsec_softc * const sc = ifp->if_softc; 963 1.2 matt 964 1.2 matt KASSERT(!cpu_intr_p()); 965 1.2 matt const uint32_t imask_gsc_mask = IEVENT_GTSC|IEVENT_GRSC; 966 1.2 matt /* 967 1.2 matt * Clear the GTSC and GRSC from the interrupt mask until 968 1.2 matt * we are ready for them. Then clear them from IEVENT, 969 1.2 matt * request the graceful shutdown, and then enable the 970 1.2 matt * GTSC and GRSC bits in the mask. This should cause the 971 1.2 matt * error interrupt to fire which will issue a wakeup to 972 1.2 matt * allow us to resume. 973 1.2 matt */ 974 1.2 matt 975 1.2 matt /* 976 1.2 matt * 1. Set GRS/GTS bits in DMACTRL register 977 1.2 matt */ 978 1.2 matt sc->sc_dmactrl |= DMACTRL_GRS|DMACTRL_GTS; 979 1.2 matt etsec_write(sc, IMASK, sc->sc_imask & ~imask_gsc_mask); 980 1.2 matt etsec_write(sc, IEVENT, imask_gsc_mask); 981 1.2 matt etsec_write(sc, DMACTRL, sc->sc_dmactrl); 982 1.2 matt 983 1.2 matt if (etsec_read(sc, MACCFG1) & (MACCFG1_TX_EN|MACCFG1_RX_EN)) { 984 1.2 matt /* 985 1.2 matt * 2. Poll GRSC/GTSC bits in IEVENT register until both are set 986 1.2 matt */ 987 1.2 matt etsec_write(sc, IMASK, sc->sc_imask | imask_gsc_mask); 988 1.2 matt 989 1.2 matt u_int timo = 1000; 990 1.2 matt uint32_t ievent = etsec_read(sc, IEVENT); 991 1.2 matt while ((ievent & imask_gsc_mask) != imask_gsc_mask) { 992 1.2 matt if (--timo == 0) { 993 1.2 matt aprint_error_dev(sc->sc_dev, 994 1.2 matt "WARNING: " 995 1.2 matt "request to stop failed (IEVENT=%#x)\n", 996 1.2 matt ievent); 997 1.2 matt break; 998 1.2 matt } 999 1.2 matt delay(10); 1000 1.2 matt ievent = etsec_read(sc, IEVENT); 1001 1.2 matt } 1002 1.2 matt } 1003 1.2 matt 1004 1.2 matt /* 1005 1.2 matt * Now reset the controller. 1006 1.2 matt * 1007 1.2 matt * 3. Set SOFT_RESET bit in MACCFG1 register 1008 1.2 matt * 4. Clear SOFT_RESET bit in MACCFG1 register 1009 1.2 matt */ 1010 1.2 matt etsec_write(sc, MACCFG1, MACCFG1_SOFT_RESET); 1011 1.2 matt etsec_write(sc, MACCFG1, 0); 1012 1.2 matt etsec_write(sc, IMASK, 0); 1013 1.2 matt etsec_write(sc, IEVENT, ~0); 1014 1.2 matt sc->sc_imask = 0; 1015 1.2 matt ifp->if_flags &= ~IFF_RUNNING; 1016 1.2 matt 1017 1.2 matt uint32_t tbipa = etsec_read(sc, TBIPA); 1018 1.2 matt if (tbipa == sc->sc_phy_addr) { 1019 1.2 matt aprint_normal_dev(sc->sc_dev, "relocating TBI\n"); 1020 1.2 matt etsec_write(sc, TBIPA, 0x1f); 1021 1.2 matt } 1022 1.2 matt uint32_t miimcfg = etsec_read(sc, MIIMCFG); 1023 1.2 matt etsec_write(sc, MIIMCFG, MIIMCFG_RESET); 1024 1.2 matt etsec_write(sc, MIIMCFG, miimcfg); 1025 1.2 matt 1026 1.2 matt /* 1027 1.2 matt * Let's consume any remaing transmitted packets. And if we are 1028 1.2 matt * disabling the interface, purge ourselves of any untransmitted 1029 1.2 matt * packets. But don't consume any received packets, just drop them. 1030 1.2 matt * If we aren't disabling the interface, save the mbufs in the 1031 1.2 matt * receive queue for reuse. 1032 1.2 matt */ 1033 1.2 matt pq3etsec_rxq_purge(sc, &sc->sc_rxq, disable); 1034 1.2 matt pq3etsec_txq_consume(sc, &sc->sc_txq); 1035 1.2 matt if (disable) { 1036 1.2 matt pq3etsec_txq_purge(sc, &sc->sc_txq); 1037 1.20 nonaka IFQ_PURGE(&ifp->if_snd); 1038 1.2 matt } 1039 1.2 matt } 1040 1.2 matt 1041 1.2 matt static void 1042 1.2 matt pq3etsec_ifwatchdog(struct ifnet *ifp) 1043 1.2 matt { 1044 1.2 matt } 1045 1.2 matt 1046 1.2 matt static void 1047 1.2 matt pq3etsec_mc_setup( 1048 1.2 matt struct pq3etsec_softc *sc) 1049 1.2 matt { 1050 1.2 matt struct ethercom * const ec = &sc->sc_ec; 1051 1.2 matt struct ifnet * const ifp = &sc->sc_if; 1052 1.2 matt struct ether_multi *enm; 1053 1.2 matt struct ether_multistep step; 1054 1.2 matt uint32_t *gaddr = sc->sc_gaddr + ((sc->sc_rctrl & RCTRL_GHTX) ? 0 : 8); 1055 1.2 matt const uint32_t crc_shift = 32 - ((sc->sc_rctrl & RCTRL_GHTX) ? 9 : 8); 1056 1.2 matt 1057 1.2 matt memset(sc->sc_gaddr, 0, sizeof(sc->sc_gaddr)); 1058 1.2 matt memset(sc->sc_macaddrs, 0, sizeof(sc->sc_macaddrs)); 1059 1.2 matt 1060 1.2 matt ifp->if_flags &= ~IFF_ALLMULTI; 1061 1.2 matt 1062 1.2 matt ETHER_FIRST_MULTI(step, ec, enm); 1063 1.2 matt for (u_int i = 0; enm != NULL; ) { 1064 1.2 matt const char *addr = enm->enm_addrlo; 1065 1.2 matt if (memcmp(addr, enm->enm_addrhi, ETHER_ADDR_LEN) != 0) { 1066 1.2 matt ifp->if_flags |= IFF_ALLMULTI; 1067 1.2 matt memset(gaddr, 0xff, 32 << (crc_shift & 1)); 1068 1.2 matt memset(sc->sc_macaddrs, 0, sizeof(sc->sc_macaddrs)); 1069 1.2 matt break; 1070 1.2 matt } 1071 1.2 matt if ((sc->sc_rctrl & RCTRL_EMEN) 1072 1.2 matt && i < __arraycount(sc->sc_macaddrs)) { 1073 1.2 matt sc->sc_macaddrs[i++] = pq3etsec_macaddr_create(addr); 1074 1.2 matt } else { 1075 1.2 matt uint32_t crc = ether_crc32_be(addr, ETHER_ADDR_LEN); 1076 1.2 matt #if 0 1077 1.2 matt printf("%s: %s: crc=%#x: %#x: [%u,%u]=%#x\n", __func__, 1078 1.2 matt ether_sprintf(addr), crc, 1079 1.2 matt crc >> crc_shift, 1080 1.2 matt crc >> (crc_shift + 5), 1081 1.2 matt (crc >> crc_shift) & 31, 1082 1.2 matt 1 << (((crc >> crc_shift) & 31) ^ 31)); 1083 1.2 matt #endif 1084 1.2 matt /* 1085 1.2 matt * The documentation doesn't completely follow PowerPC 1086 1.2 matt * bit order. The BE crc32 (H) for 01:00:5E:00:00:01 1087 1.2 matt * is 0x7fa32d9b. By empirical testing, the 1088 1.2 matt * corresponding hash bit is word 3, bit 31 (ppc bit 1089 1.2 matt * order). Since 3 << 31 | 31 is 0x7f, we deduce 1090 1.2 matt * H[0:2] selects the register while H[3:7] selects 1091 1.2 matt * the bit (ppc bit order). 1092 1.2 matt */ 1093 1.2 matt crc >>= crc_shift; 1094 1.2 matt gaddr[crc / 32] |= 1 << ((crc & 31) ^ 31); 1095 1.2 matt } 1096 1.2 matt ETHER_NEXT_MULTI(step, enm); 1097 1.2 matt } 1098 1.2 matt for (u_int i = 0; i < 8; i++) { 1099 1.2 matt etsec_write(sc, IGADDR(i), sc->sc_gaddr[i]); 1100 1.2 matt etsec_write(sc, GADDR(i), sc->sc_gaddr[i+8]); 1101 1.2 matt #if 0 1102 1.2 matt if (sc->sc_gaddr[i] || sc->sc_gaddr[i+8]) 1103 1.2 matt printf("%s: IGADDR%u(%#x)=%#x GADDR%u(%#x)=%#x\n", __func__, 1104 1.2 matt i, IGADDR(i), etsec_read(sc, IGADDR(i)), 1105 1.2 matt i, GADDR(i), etsec_read(sc, GADDR(i))); 1106 1.2 matt #endif 1107 1.2 matt } 1108 1.2 matt for (u_int i = 0; i < __arraycount(sc->sc_macaddrs); i++) { 1109 1.2 matt uint64_t macaddr = sc->sc_macaddrs[i]; 1110 1.2 matt etsec_write(sc, MACnADDR1(i), (uint32_t)(macaddr >> 32)); 1111 1.2 matt etsec_write(sc, MACnADDR2(i), (uint32_t)(macaddr >> 0)); 1112 1.2 matt #if 0 1113 1.2 matt if (macaddr) 1114 1.2 matt printf("%s: MAC%02uADDR2(%08x)=%#x MAC%02uADDR2(%#x)=%08x\n", __func__, 1115 1.2 matt i+1, MACnADDR1(i), etsec_read(sc, MACnADDR1(i)), 1116 1.2 matt i+1, MACnADDR2(i), etsec_read(sc, MACnADDR2(i))); 1117 1.2 matt #endif 1118 1.2 matt } 1119 1.2 matt } 1120 1.2 matt 1121 1.2 matt static int 1122 1.2 matt pq3etsec_ifioctl(struct ifnet *ifp, u_long cmd, void *data) 1123 1.2 matt { 1124 1.2 matt struct pq3etsec_softc *sc = ifp->if_softc; 1125 1.2 matt struct ifreq * const ifr = data; 1126 1.2 matt const int s = splnet(); 1127 1.2 matt int error; 1128 1.2 matt 1129 1.2 matt switch (cmd) { 1130 1.2 matt case SIOCSIFMEDIA: 1131 1.2 matt case SIOCGIFMEDIA: 1132 1.2 matt /* Flow control requires full-duplex mode. */ 1133 1.2 matt if (IFM_SUBTYPE(ifr->ifr_media) == IFM_AUTO || 1134 1.2 matt (ifr->ifr_media & IFM_FDX) == 0) 1135 1.2 matt ifr->ifr_media &= ~IFM_ETH_FMASK; 1136 1.2 matt if (IFM_SUBTYPE(ifr->ifr_media) != IFM_AUTO) { 1137 1.2 matt if ((ifr->ifr_media & IFM_ETH_FMASK) == IFM_FLOW) { 1138 1.2 matt /* We can do both TXPAUSE and RXPAUSE. */ 1139 1.2 matt ifr->ifr_media |= 1140 1.2 matt IFM_ETH_TXPAUSE | IFM_ETH_RXPAUSE; 1141 1.2 matt } 1142 1.2 matt } 1143 1.2 matt error = ifmedia_ioctl(ifp, ifr, &sc->sc_mii.mii_media, cmd); 1144 1.2 matt break; 1145 1.2 matt 1146 1.2 matt default: 1147 1.2 matt error = ether_ioctl(ifp, cmd, data); 1148 1.2 matt if (error != ENETRESET) 1149 1.2 matt break; 1150 1.2 matt 1151 1.2 matt if (cmd == SIOCADDMULTI || cmd == SIOCDELMULTI) { 1152 1.2 matt error = 0; 1153 1.2 matt if (ifp->if_flags & IFF_RUNNING) 1154 1.2 matt pq3etsec_mc_setup(sc); 1155 1.2 matt break; 1156 1.2 matt } 1157 1.2 matt error = pq3etsec_ifinit(ifp); 1158 1.2 matt break; 1159 1.2 matt } 1160 1.2 matt 1161 1.2 matt splx(s); 1162 1.2 matt return error; 1163 1.2 matt } 1164 1.2 matt 1165 1.2 matt static void 1166 1.2 matt pq3etsec_rxq_desc_presync( 1167 1.2 matt struct pq3etsec_softc *sc, 1168 1.2 matt struct pq3etsec_rxqueue *rxq, 1169 1.2 matt volatile struct rxbd *rxbd, 1170 1.2 matt size_t count) 1171 1.2 matt { 1172 1.2 matt bus_dmamap_sync(sc->sc_dmat, rxq->rxq_descmap, 1173 1.2 matt (rxbd - rxq->rxq_first) * sizeof(*rxbd), count * sizeof(*rxbd), 1174 1.2 matt BUS_DMASYNC_PREREAD|BUS_DMASYNC_PREWRITE); 1175 1.2 matt } 1176 1.2 matt 1177 1.2 matt static void 1178 1.2 matt pq3etsec_rxq_desc_postsync( 1179 1.2 matt struct pq3etsec_softc *sc, 1180 1.2 matt struct pq3etsec_rxqueue *rxq, 1181 1.2 matt volatile struct rxbd *rxbd, 1182 1.2 matt size_t count) 1183 1.2 matt { 1184 1.2 matt bus_dmamap_sync(sc->sc_dmat, rxq->rxq_descmap, 1185 1.2 matt (rxbd - rxq->rxq_first) * sizeof(*rxbd), count * sizeof(*rxbd), 1186 1.2 matt BUS_DMASYNC_POSTREAD|BUS_DMASYNC_POSTWRITE); 1187 1.2 matt } 1188 1.2 matt 1189 1.2 matt static void 1190 1.2 matt pq3etsec_txq_desc_presync( 1191 1.2 matt struct pq3etsec_softc *sc, 1192 1.2 matt struct pq3etsec_txqueue *txq, 1193 1.2 matt volatile struct txbd *txbd, 1194 1.2 matt size_t count) 1195 1.2 matt { 1196 1.2 matt bus_dmamap_sync(sc->sc_dmat, txq->txq_descmap, 1197 1.2 matt (txbd - txq->txq_first) * sizeof(*txbd), count * sizeof(*txbd), 1198 1.2 matt BUS_DMASYNC_PREREAD|BUS_DMASYNC_PREWRITE); 1199 1.2 matt } 1200 1.2 matt 1201 1.2 matt static void 1202 1.2 matt pq3etsec_txq_desc_postsync( 1203 1.2 matt struct pq3etsec_softc *sc, 1204 1.2 matt struct pq3etsec_txqueue *txq, 1205 1.2 matt volatile struct txbd *txbd, 1206 1.2 matt size_t count) 1207 1.2 matt { 1208 1.2 matt bus_dmamap_sync(sc->sc_dmat, txq->txq_descmap, 1209 1.2 matt (txbd - txq->txq_first) * sizeof(*txbd), count * sizeof(*txbd), 1210 1.2 matt BUS_DMASYNC_POSTREAD|BUS_DMASYNC_POSTWRITE); 1211 1.2 matt } 1212 1.2 matt 1213 1.2 matt static bus_dmamap_t 1214 1.2 matt pq3etsec_mapcache_get( 1215 1.2 matt struct pq3etsec_softc *sc, 1216 1.2 matt struct pq3etsec_mapcache *dmc) 1217 1.2 matt { 1218 1.10 matt KASSERT(dmc->dmc_nmaps > 0); 1219 1.2 matt KASSERT(dmc->dmc_maps[dmc->dmc_nmaps-1] != NULL); 1220 1.2 matt return dmc->dmc_maps[--dmc->dmc_nmaps]; 1221 1.2 matt } 1222 1.2 matt 1223 1.2 matt static void 1224 1.2 matt pq3etsec_mapcache_put( 1225 1.2 matt struct pq3etsec_softc *sc, 1226 1.2 matt struct pq3etsec_mapcache *dmc, 1227 1.2 matt bus_dmamap_t map) 1228 1.2 matt { 1229 1.2 matt KASSERT(map != NULL); 1230 1.2 matt KASSERT(dmc->dmc_nmaps < dmc->dmc_maxmaps); 1231 1.2 matt dmc->dmc_maps[dmc->dmc_nmaps++] = map; 1232 1.2 matt } 1233 1.2 matt 1234 1.2 matt static void 1235 1.2 matt pq3etsec_mapcache_destroy( 1236 1.2 matt struct pq3etsec_softc *sc, 1237 1.2 matt struct pq3etsec_mapcache *dmc) 1238 1.2 matt { 1239 1.2 matt const size_t dmc_size = 1240 1.2 matt offsetof(struct pq3etsec_mapcache, dmc_maps[dmc->dmc_maxmaps]); 1241 1.2 matt 1242 1.2 matt for (u_int i = 0; i < dmc->dmc_maxmaps; i++) { 1243 1.2 matt bus_dmamap_destroy(sc->sc_dmat, dmc->dmc_maps[i]); 1244 1.2 matt } 1245 1.14 matt kmem_intr_free(dmc, dmc_size); 1246 1.2 matt } 1247 1.2 matt 1248 1.2 matt static int 1249 1.2 matt pq3etsec_mapcache_create( 1250 1.2 matt struct pq3etsec_softc *sc, 1251 1.2 matt struct pq3etsec_mapcache **dmc_p, 1252 1.2 matt size_t maxmaps, 1253 1.2 matt size_t maxmapsize, 1254 1.2 matt size_t maxseg) 1255 1.2 matt { 1256 1.2 matt const size_t dmc_size = 1257 1.2 matt offsetof(struct pq3etsec_mapcache, dmc_maps[maxmaps]); 1258 1.14 matt struct pq3etsec_mapcache * const dmc = 1259 1.14 matt kmem_intr_zalloc(dmc_size, KM_NOSLEEP); 1260 1.2 matt 1261 1.2 matt dmc->dmc_maxmaps = maxmaps; 1262 1.10 matt dmc->dmc_nmaps = maxmaps; 1263 1.2 matt dmc->dmc_maxmapsize = maxmapsize; 1264 1.2 matt dmc->dmc_maxseg = maxseg; 1265 1.2 matt 1266 1.10 matt for (u_int i = 0; i < maxmaps; i++) { 1267 1.2 matt int error = bus_dmamap_create(sc->sc_dmat, dmc->dmc_maxmapsize, 1268 1.2 matt dmc->dmc_maxseg, dmc->dmc_maxmapsize, 0, 1269 1.2 matt BUS_DMA_WAITOK|BUS_DMA_ALLOCNOW, &dmc->dmc_maps[i]); 1270 1.2 matt if (error) { 1271 1.2 matt aprint_error_dev(sc->sc_dev, 1272 1.2 matt "failed to creat dma map cache " 1273 1.10 matt "entry %u of %zu: %d\n", 1274 1.10 matt i, maxmaps, error); 1275 1.2 matt while (i-- > 0) { 1276 1.2 matt bus_dmamap_destroy(sc->sc_dmat, 1277 1.2 matt dmc->dmc_maps[i]); 1278 1.2 matt } 1279 1.14 matt kmem_intr_free(dmc, dmc_size); 1280 1.2 matt return error; 1281 1.2 matt } 1282 1.2 matt KASSERT(dmc->dmc_maps[i] != NULL); 1283 1.2 matt } 1284 1.2 matt 1285 1.2 matt *dmc_p = dmc; 1286 1.2 matt 1287 1.2 matt return 0; 1288 1.2 matt } 1289 1.2 matt 1290 1.2 matt #if 0 1291 1.2 matt static void 1292 1.2 matt pq3etsec_dmamem_free( 1293 1.2 matt bus_dma_tag_t dmat, 1294 1.2 matt size_t map_size, 1295 1.2 matt bus_dma_segment_t *seg, 1296 1.2 matt bus_dmamap_t map, 1297 1.2 matt void *kvap) 1298 1.2 matt { 1299 1.2 matt bus_dmamap_destroy(dmat, map); 1300 1.2 matt bus_dmamem_unmap(dmat, kvap, map_size); 1301 1.2 matt bus_dmamem_free(dmat, seg, 1); 1302 1.2 matt } 1303 1.2 matt #endif 1304 1.2 matt 1305 1.2 matt static int 1306 1.2 matt pq3etsec_dmamem_alloc( 1307 1.2 matt bus_dma_tag_t dmat, 1308 1.2 matt size_t map_size, 1309 1.2 matt bus_dma_segment_t *seg, 1310 1.2 matt bus_dmamap_t *map, 1311 1.2 matt void **kvap) 1312 1.2 matt { 1313 1.2 matt int error; 1314 1.2 matt int nseg; 1315 1.2 matt 1316 1.2 matt *kvap = NULL; 1317 1.2 matt *map = NULL; 1318 1.2 matt 1319 1.2 matt error = bus_dmamem_alloc(dmat, map_size, PAGE_SIZE, 0, 1320 1.2 matt seg, 1, &nseg, 0); 1321 1.2 matt if (error) 1322 1.2 matt return error; 1323 1.2 matt 1324 1.2 matt KASSERT(nseg == 1); 1325 1.2 matt 1326 1.2 matt error = bus_dmamem_map(dmat, seg, nseg, map_size, (void **)kvap, 1327 1.2 matt BUS_DMA_COHERENT); 1328 1.2 matt if (error == 0) { 1329 1.2 matt error = bus_dmamap_create(dmat, map_size, 1, map_size, 0, 0, 1330 1.2 matt map); 1331 1.2 matt if (error == 0) { 1332 1.2 matt error = bus_dmamap_load(dmat, *map, *kvap, map_size, 1333 1.2 matt NULL, 0); 1334 1.2 matt if (error == 0) 1335 1.2 matt return 0; 1336 1.2 matt bus_dmamap_destroy(dmat, *map); 1337 1.2 matt *map = NULL; 1338 1.2 matt } 1339 1.2 matt bus_dmamem_unmap(dmat, *kvap, map_size); 1340 1.2 matt *kvap = NULL; 1341 1.2 matt } 1342 1.2 matt bus_dmamem_free(dmat, seg, nseg); 1343 1.2 matt return 0; 1344 1.2 matt } 1345 1.2 matt 1346 1.2 matt static struct mbuf * 1347 1.2 matt pq3etsec_rx_buf_alloc( 1348 1.2 matt struct pq3etsec_softc *sc) 1349 1.2 matt { 1350 1.2 matt struct mbuf *m = m_gethdr(M_DONTWAIT, MT_DATA); 1351 1.2 matt if (m == NULL) { 1352 1.2 matt printf("%s:%d: %s\n", __func__, __LINE__, "m_gethdr"); 1353 1.2 matt return NULL; 1354 1.2 matt } 1355 1.2 matt MCLGET(m, M_DONTWAIT); 1356 1.2 matt if ((m->m_flags & M_EXT) == 0) { 1357 1.2 matt printf("%s:%d: %s\n", __func__, __LINE__, "MCLGET"); 1358 1.2 matt m_freem(m); 1359 1.2 matt return NULL; 1360 1.2 matt } 1361 1.2 matt m->m_len = m->m_pkthdr.len = m->m_ext.ext_size; 1362 1.2 matt 1363 1.2 matt bus_dmamap_t map = pq3etsec_mapcache_get(sc, sc->sc_rx_mapcache); 1364 1.2 matt if (map == NULL) { 1365 1.2 matt printf("%s:%d: %s\n", __func__, __LINE__, "map get"); 1366 1.2 matt m_freem(m); 1367 1.2 matt return NULL; 1368 1.2 matt } 1369 1.2 matt M_SETCTX(m, map); 1370 1.2 matt m->m_len = m->m_pkthdr.len = MCLBYTES; 1371 1.2 matt int error = bus_dmamap_load_mbuf(sc->sc_dmat, map, m, 1372 1.2 matt BUS_DMA_READ|BUS_DMA_NOWAIT); 1373 1.2 matt if (error) { 1374 1.2 matt aprint_error_dev(sc->sc_dev, "fail to load rx dmamap: %d\n", 1375 1.2 matt error); 1376 1.2 matt M_SETCTX(m, NULL); 1377 1.2 matt m_freem(m); 1378 1.2 matt pq3etsec_mapcache_put(sc, sc->sc_rx_mapcache, map); 1379 1.2 matt return NULL; 1380 1.2 matt } 1381 1.2 matt KASSERT(map->dm_mapsize == MCLBYTES); 1382 1.2 matt bus_dmamap_sync(sc->sc_dmat, map, 0, map->dm_mapsize, 1383 1.2 matt BUS_DMASYNC_PREREAD); 1384 1.2 matt 1385 1.2 matt return m; 1386 1.2 matt } 1387 1.2 matt 1388 1.2 matt static void 1389 1.2 matt pq3etsec_rx_map_unload( 1390 1.2 matt struct pq3etsec_softc *sc, 1391 1.2 matt struct mbuf *m) 1392 1.2 matt { 1393 1.2 matt KASSERT(m); 1394 1.2 matt for (; m != NULL; m = m->m_next) { 1395 1.2 matt bus_dmamap_t map = M_GETCTX(m, bus_dmamap_t); 1396 1.2 matt KASSERT(map); 1397 1.2 matt KASSERT(map->dm_mapsize == MCLBYTES); 1398 1.2 matt bus_dmamap_sync(sc->sc_dmat, map, 0, m->m_len, 1399 1.2 matt BUS_DMASYNC_POSTREAD); 1400 1.2 matt bus_dmamap_unload(sc->sc_dmat, map); 1401 1.2 matt pq3etsec_mapcache_put(sc, sc->sc_rx_mapcache, map); 1402 1.2 matt M_SETCTX(m, NULL); 1403 1.2 matt } 1404 1.2 matt } 1405 1.2 matt 1406 1.2 matt static bool 1407 1.2 matt pq3etsec_rxq_produce( 1408 1.2 matt struct pq3etsec_softc *sc, 1409 1.2 matt struct pq3etsec_rxqueue *rxq) 1410 1.2 matt { 1411 1.2 matt volatile struct rxbd *producer = rxq->rxq_producer; 1412 1.2 matt #if 0 1413 1.2 matt size_t inuse = rxq->rxq_inuse; 1414 1.2 matt #endif 1415 1.2 matt while (rxq->rxq_inuse < rxq->rxq_threshold) { 1416 1.2 matt struct mbuf *m; 1417 1.2 matt IF_DEQUEUE(&sc->sc_rx_bufcache, m); 1418 1.2 matt if (m == NULL) { 1419 1.2 matt m = pq3etsec_rx_buf_alloc(sc); 1420 1.2 matt if (m == NULL) { 1421 1.2 matt printf("%s: pq3etsec_rx_buf_alloc failed\n", __func__); 1422 1.2 matt break; 1423 1.2 matt } 1424 1.2 matt } 1425 1.2 matt bus_dmamap_t map = M_GETCTX(m, bus_dmamap_t); 1426 1.2 matt KASSERT(map); 1427 1.2 matt 1428 1.2 matt #ifdef ETSEC_DEBUG 1429 1.2 matt KASSERT(rxq->rxq_mbufs[producer-rxq->rxq_first] == NULL); 1430 1.2 matt rxq->rxq_mbufs[producer-rxq->rxq_first] = m; 1431 1.2 matt #endif 1432 1.2 matt 1433 1.2 matt /* rxbd_len is write-only by the ETSEC */ 1434 1.2 matt producer->rxbd_bufptr = map->dm_segs[0].ds_addr; 1435 1.2 matt membar_producer(); 1436 1.2 matt producer->rxbd_flags |= RXBD_E; 1437 1.2 matt if (__predict_false(rxq->rxq_mhead == NULL)) { 1438 1.2 matt KASSERT(producer == rxq->rxq_consumer); 1439 1.2 matt rxq->rxq_mconsumer = m; 1440 1.2 matt } 1441 1.2 matt *rxq->rxq_mtail = m; 1442 1.2 matt rxq->rxq_mtail = &m->m_next; 1443 1.2 matt m->m_len = MCLBYTES; 1444 1.2 matt m->m_next = NULL; 1445 1.2 matt rxq->rxq_inuse++; 1446 1.2 matt if (++producer == rxq->rxq_last) { 1447 1.2 matt membar_producer(); 1448 1.2 matt pq3etsec_rxq_desc_presync(sc, rxq, rxq->rxq_producer, 1449 1.2 matt rxq->rxq_last - rxq->rxq_producer); 1450 1.2 matt producer = rxq->rxq_producer = rxq->rxq_first; 1451 1.2 matt } 1452 1.2 matt } 1453 1.2 matt if (producer != rxq->rxq_producer) { 1454 1.2 matt membar_producer(); 1455 1.2 matt pq3etsec_rxq_desc_presync(sc, rxq, rxq->rxq_producer, 1456 1.2 matt producer - rxq->rxq_producer); 1457 1.2 matt rxq->rxq_producer = producer; 1458 1.2 matt } 1459 1.2 matt uint32_t qhlt = etsec_read(sc, RSTAT) & RSTAT_QHLT; 1460 1.2 matt if (qhlt) { 1461 1.2 matt KASSERT(qhlt & rxq->rxq_qmask); 1462 1.2 matt sc->sc_ev_rx_stall.ev_count++; 1463 1.2 matt etsec_write(sc, RSTAT, RSTAT_QHLT & rxq->rxq_qmask); 1464 1.2 matt } 1465 1.2 matt #if 0 1466 1.2 matt aprint_normal_dev(sc->sc_dev, 1467 1.2 matt "%s: buffers inuse went from %zu to %zu\n", 1468 1.2 matt __func__, inuse, rxq->rxq_inuse); 1469 1.2 matt #endif 1470 1.2 matt return true; 1471 1.2 matt } 1472 1.2 matt 1473 1.2 matt static bool 1474 1.2 matt pq3etsec_rx_offload( 1475 1.2 matt struct pq3etsec_softc *sc, 1476 1.2 matt struct mbuf *m, 1477 1.2 matt const struct rxfcb *fcb) 1478 1.2 matt { 1479 1.2 matt if (fcb->rxfcb_flags & RXFCB_VLN) { 1480 1.2 matt VLAN_INPUT_TAG(&sc->sc_if, m, fcb->rxfcb_vlctl, 1481 1.2 matt m_freem(m); return false); 1482 1.2 matt } 1483 1.2 matt if ((fcb->rxfcb_flags & RXFCB_IP) == 0 1484 1.2 matt || (fcb->rxfcb_flags & (RXFCB_CIP|RXFCB_CTU)) == 0) 1485 1.2 matt return true; 1486 1.2 matt int csum_flags = 0; 1487 1.2 matt if ((fcb->rxfcb_flags & (RXFCB_IP6|RXFCB_CIP)) == RXFCB_CIP) { 1488 1.2 matt csum_flags |= M_CSUM_IPv4; 1489 1.2 matt if (fcb->rxfcb_flags & RXFCB_EIP) 1490 1.2 matt csum_flags |= M_CSUM_IPv4_BAD; 1491 1.2 matt } 1492 1.2 matt if ((fcb->rxfcb_flags & RXFCB_CTU) == RXFCB_CTU) { 1493 1.2 matt int ipv_flags; 1494 1.2 matt if (fcb->rxfcb_flags & RXFCB_IP6) 1495 1.2 matt ipv_flags = M_CSUM_TCPv6|M_CSUM_UDPv6; 1496 1.2 matt else 1497 1.2 matt ipv_flags = M_CSUM_TCPv4|M_CSUM_UDPv4; 1498 1.2 matt if (fcb->rxfcb_pro == IPPROTO_TCP) { 1499 1.2 matt csum_flags |= (M_CSUM_TCPv4|M_CSUM_TCPv6) & ipv_flags; 1500 1.2 matt } else { 1501 1.2 matt csum_flags |= (M_CSUM_UDPv4|M_CSUM_UDPv6) & ipv_flags; 1502 1.2 matt } 1503 1.2 matt if (fcb->rxfcb_flags & RXFCB_ETU) 1504 1.2 matt csum_flags |= M_CSUM_TCP_UDP_BAD; 1505 1.2 matt } 1506 1.2 matt 1507 1.2 matt m->m_pkthdr.csum_flags = csum_flags; 1508 1.2 matt return true; 1509 1.2 matt } 1510 1.2 matt 1511 1.2 matt static void 1512 1.2 matt pq3etsec_rx_input( 1513 1.2 matt struct pq3etsec_softc *sc, 1514 1.2 matt struct mbuf *m, 1515 1.2 matt uint16_t rxbd_flags) 1516 1.2 matt { 1517 1.2 matt struct ifnet * const ifp = &sc->sc_if; 1518 1.2 matt 1519 1.2 matt pq3etsec_rx_map_unload(sc, m); 1520 1.2 matt 1521 1.2 matt if ((sc->sc_rctrl & RCTRL_PRSDEP) != RCTRL_PRSDEP_OFF) { 1522 1.2 matt struct rxfcb fcb = *mtod(m, struct rxfcb *); 1523 1.2 matt if (!pq3etsec_rx_offload(sc, m, &fcb)) 1524 1.2 matt return; 1525 1.2 matt } 1526 1.2 matt m_adj(m, sc->sc_rx_adjlen); 1527 1.2 matt 1528 1.2 matt if (rxbd_flags & RXBD_M) 1529 1.2 matt m->m_flags |= M_PROMISC; 1530 1.2 matt if (rxbd_flags & RXBD_BC) 1531 1.2 matt m->m_flags |= M_BCAST; 1532 1.2 matt if (rxbd_flags & RXBD_MC) 1533 1.2 matt m->m_flags |= M_MCAST; 1534 1.2 matt m->m_flags |= M_HASFCS; 1535 1.2 matt m->m_pkthdr.rcvif = &sc->sc_if; 1536 1.2 matt 1537 1.2 matt ifp->if_ipackets++; 1538 1.2 matt ifp->if_ibytes += m->m_pkthdr.len; 1539 1.2 matt 1540 1.2 matt /* 1541 1.2 matt * Let's give it to the network subsystm to deal with. 1542 1.2 matt */ 1543 1.2 matt int s = splnet(); 1544 1.2 matt bpf_mtap(ifp, m); 1545 1.2 matt (*ifp->if_input)(ifp, m); 1546 1.2 matt splx(s); 1547 1.2 matt } 1548 1.2 matt 1549 1.2 matt static void 1550 1.2 matt pq3etsec_rxq_consume( 1551 1.2 matt struct pq3etsec_softc *sc, 1552 1.2 matt struct pq3etsec_rxqueue *rxq) 1553 1.2 matt { 1554 1.2 matt struct ifnet * const ifp = &sc->sc_if; 1555 1.2 matt volatile struct rxbd *consumer = rxq->rxq_consumer; 1556 1.2 matt size_t rxconsumed = 0; 1557 1.2 matt 1558 1.2 matt etsec_write(sc, RSTAT, RSTAT_RXF & rxq->rxq_qmask); 1559 1.2 matt 1560 1.2 matt for (;;) { 1561 1.2 matt if (consumer == rxq->rxq_producer) { 1562 1.2 matt rxq->rxq_consumer = consumer; 1563 1.2 matt rxq->rxq_inuse -= rxconsumed; 1564 1.4 matt KASSERT(rxq->rxq_inuse == 0); 1565 1.2 matt return; 1566 1.2 matt } 1567 1.2 matt pq3etsec_rxq_desc_postsync(sc, rxq, consumer, 1); 1568 1.2 matt const uint16_t rxbd_flags = consumer->rxbd_flags; 1569 1.2 matt if (rxbd_flags & RXBD_E) { 1570 1.2 matt rxq->rxq_consumer = consumer; 1571 1.2 matt rxq->rxq_inuse -= rxconsumed; 1572 1.2 matt return; 1573 1.2 matt } 1574 1.2 matt KASSERT(rxq->rxq_mconsumer != NULL); 1575 1.2 matt #ifdef ETSEC_DEBUG 1576 1.2 matt KASSERT(rxq->rxq_mbufs[consumer - rxq->rxq_first] == rxq->rxq_mconsumer); 1577 1.2 matt #endif 1578 1.2 matt #if 0 1579 1.2 matt printf("%s: rxdb[%u]: flags=%#x len=%#x: %08x %08x %08x %08x\n", 1580 1.2 matt __func__, 1581 1.2 matt consumer - rxq->rxq_first, rxbd_flags, consumer->rxbd_len, 1582 1.2 matt mtod(rxq->rxq_mconsumer, int *)[0], 1583 1.2 matt mtod(rxq->rxq_mconsumer, int *)[1], 1584 1.2 matt mtod(rxq->rxq_mconsumer, int *)[2], 1585 1.2 matt mtod(rxq->rxq_mconsumer, int *)[3]); 1586 1.2 matt #endif 1587 1.2 matt /* 1588 1.2 matt * We own this packet again. Clear all flags except wrap. 1589 1.2 matt */ 1590 1.2 matt rxconsumed++; 1591 1.2 matt consumer->rxbd_flags = rxbd_flags & (RXBD_W|RXBD_I); 1592 1.2 matt 1593 1.2 matt /* 1594 1.2 matt * If this descriptor has the LAST bit set and no errors, 1595 1.2 matt * it's a valid input packet. 1596 1.2 matt */ 1597 1.2 matt if ((rxbd_flags & (RXBD_L|RXBD_ERRORS)) == RXBD_L) { 1598 1.2 matt size_t rxbd_len = consumer->rxbd_len; 1599 1.2 matt struct mbuf *m = rxq->rxq_mhead; 1600 1.2 matt struct mbuf *m_last = rxq->rxq_mconsumer; 1601 1.2 matt if ((rxq->rxq_mhead = m_last->m_next) == NULL) 1602 1.2 matt rxq->rxq_mtail = &rxq->rxq_mhead; 1603 1.2 matt rxq->rxq_mconsumer = rxq->rxq_mhead; 1604 1.2 matt m_last->m_next = NULL; 1605 1.2 matt m_last->m_len = rxbd_len & (MCLBYTES - 1); 1606 1.2 matt m->m_pkthdr.len = rxbd_len; 1607 1.2 matt pq3etsec_rx_input(sc, m, rxbd_flags); 1608 1.2 matt } else if (rxbd_flags & RXBD_L) { 1609 1.2 matt KASSERT(rxbd_flags & RXBD_ERRORS); 1610 1.2 matt struct mbuf *m; 1611 1.2 matt /* 1612 1.2 matt * We encountered an error, take the mbufs and add 1613 1.2 matt * then to the rx bufcache so we can reuse them. 1614 1.2 matt */ 1615 1.2 matt ifp->if_ierrors++; 1616 1.2 matt for (m = rxq->rxq_mhead; 1617 1.2 matt m != rxq->rxq_mconsumer; 1618 1.2 matt m = m->m_next) { 1619 1.2 matt IF_ENQUEUE(&sc->sc_rx_bufcache, m); 1620 1.2 matt } 1621 1.2 matt m = rxq->rxq_mconsumer; 1622 1.2 matt if ((rxq->rxq_mhead = m->m_next) == NULL) 1623 1.2 matt rxq->rxq_mtail = &rxq->rxq_mhead; 1624 1.2 matt rxq->rxq_mconsumer = m->m_next; 1625 1.2 matt IF_ENQUEUE(&sc->sc_rx_bufcache, m); 1626 1.2 matt } else { 1627 1.2 matt rxq->rxq_mconsumer = rxq->rxq_mconsumer->m_next; 1628 1.2 matt } 1629 1.2 matt #ifdef ETSEC_DEBUG 1630 1.2 matt rxq->rxq_mbufs[consumer - rxq->rxq_first] = NULL; 1631 1.2 matt #endif 1632 1.2 matt 1633 1.2 matt /* 1634 1.2 matt * Wrap at the last entry! 1635 1.2 matt */ 1636 1.2 matt if (rxbd_flags & RXBD_W) { 1637 1.2 matt KASSERT(consumer + 1 == rxq->rxq_last); 1638 1.2 matt consumer = rxq->rxq_first; 1639 1.2 matt } else { 1640 1.2 matt consumer++; 1641 1.2 matt } 1642 1.2 matt #ifdef ETSEC_DEBUG 1643 1.2 matt KASSERT(rxq->rxq_mbufs[consumer - rxq->rxq_first] == rxq->rxq_mconsumer); 1644 1.2 matt #endif 1645 1.2 matt } 1646 1.2 matt } 1647 1.2 matt 1648 1.2 matt static void 1649 1.2 matt pq3etsec_rxq_purge( 1650 1.2 matt struct pq3etsec_softc *sc, 1651 1.2 matt struct pq3etsec_rxqueue *rxq, 1652 1.2 matt bool discard) 1653 1.2 matt { 1654 1.2 matt struct mbuf *m; 1655 1.2 matt 1656 1.2 matt if ((m = rxq->rxq_mhead) != NULL) { 1657 1.2 matt #ifdef ETSEC_DEBUG 1658 1.2 matt memset(rxq->rxq_mbufs, 0, sizeof(rxq->rxq_mbufs)); 1659 1.2 matt #endif 1660 1.2 matt 1661 1.2 matt if (discard) { 1662 1.2 matt pq3etsec_rx_map_unload(sc, m); 1663 1.2 matt m_freem(m); 1664 1.2 matt } else { 1665 1.2 matt while (m != NULL) { 1666 1.2 matt struct mbuf *m0 = m->m_next; 1667 1.2 matt m->m_next = NULL; 1668 1.2 matt IF_ENQUEUE(&sc->sc_rx_bufcache, m); 1669 1.2 matt m = m0; 1670 1.2 matt } 1671 1.2 matt } 1672 1.2 matt 1673 1.2 matt } 1674 1.2 matt 1675 1.2 matt rxq->rxq_mconsumer = NULL; 1676 1.2 matt rxq->rxq_mhead = NULL; 1677 1.2 matt rxq->rxq_mtail = &rxq->rxq_mhead; 1678 1.2 matt rxq->rxq_inuse = 0; 1679 1.2 matt } 1680 1.2 matt 1681 1.2 matt static void 1682 1.2 matt pq3etsec_rxq_reset( 1683 1.2 matt struct pq3etsec_softc *sc, 1684 1.2 matt struct pq3etsec_rxqueue *rxq) 1685 1.2 matt { 1686 1.2 matt /* 1687 1.2 matt * sync all the descriptors 1688 1.2 matt */ 1689 1.2 matt pq3etsec_rxq_desc_postsync(sc, rxq, rxq->rxq_first, 1690 1.2 matt rxq->rxq_last - rxq->rxq_first); 1691 1.2 matt 1692 1.2 matt /* 1693 1.2 matt * Make sure we own all descriptors in the ring. 1694 1.2 matt */ 1695 1.2 matt volatile struct rxbd *rxbd; 1696 1.2 matt for (rxbd = rxq->rxq_first; rxbd < rxq->rxq_last - 1; rxbd++) { 1697 1.2 matt rxbd->rxbd_flags = RXBD_I; 1698 1.2 matt } 1699 1.2 matt 1700 1.2 matt /* 1701 1.2 matt * Last descriptor has the wrap flag. 1702 1.2 matt */ 1703 1.2 matt rxbd->rxbd_flags = RXBD_W|RXBD_I; 1704 1.2 matt 1705 1.2 matt /* 1706 1.2 matt * Reset the producer consumer indexes. 1707 1.2 matt */ 1708 1.2 matt rxq->rxq_consumer = rxq->rxq_first; 1709 1.2 matt rxq->rxq_producer = rxq->rxq_first; 1710 1.2 matt rxq->rxq_inuse = 0; 1711 1.2 matt if (rxq->rxq_threshold < ETSEC_MINRXMBUFS) 1712 1.2 matt rxq->rxq_threshold = ETSEC_MINRXMBUFS; 1713 1.2 matt 1714 1.2 matt sc->sc_imask |= IEVENT_RXF|IEVENT_BSY; 1715 1.2 matt 1716 1.2 matt /* 1717 1.2 matt * Restart the transmit at the first descriptor 1718 1.2 matt */ 1719 1.2 matt etsec_write(sc, rxq->rxq_reg_rbase, rxq->rxq_descmap->dm_segs->ds_addr); 1720 1.2 matt } 1721 1.2 matt 1722 1.2 matt static int 1723 1.2 matt pq3etsec_rxq_attach( 1724 1.2 matt struct pq3etsec_softc *sc, 1725 1.2 matt struct pq3etsec_rxqueue *rxq, 1726 1.2 matt u_int qno) 1727 1.2 matt { 1728 1.2 matt size_t map_size = PAGE_SIZE; 1729 1.2 matt size_t desc_count = map_size / sizeof(struct rxbd); 1730 1.2 matt int error; 1731 1.2 matt void *descs; 1732 1.2 matt 1733 1.2 matt error = pq3etsec_dmamem_alloc(sc->sc_dmat, map_size, 1734 1.2 matt &rxq->rxq_descmap_seg, &rxq->rxq_descmap, &descs); 1735 1.2 matt if (error) 1736 1.2 matt return error; 1737 1.2 matt 1738 1.2 matt memset(descs, 0, map_size); 1739 1.2 matt rxq->rxq_first = descs; 1740 1.2 matt rxq->rxq_last = rxq->rxq_first + desc_count; 1741 1.2 matt rxq->rxq_consumer = descs; 1742 1.2 matt rxq->rxq_producer = descs; 1743 1.2 matt 1744 1.2 matt pq3etsec_rxq_purge(sc, rxq, true); 1745 1.2 matt pq3etsec_rxq_reset(sc, rxq); 1746 1.2 matt 1747 1.2 matt rxq->rxq_reg_rbase = RBASEn(qno); 1748 1.2 matt rxq->rxq_qmask = RSTAT_QHLTn(qno) | RSTAT_RXFn(qno); 1749 1.2 matt 1750 1.2 matt return 0; 1751 1.2 matt } 1752 1.2 matt 1753 1.2 matt static bool 1754 1.2 matt pq3etsec_txq_active_p( 1755 1.2 matt struct pq3etsec_softc * const sc, 1756 1.2 matt struct pq3etsec_txqueue *txq) 1757 1.2 matt { 1758 1.2 matt return !IF_IS_EMPTY(&txq->txq_mbufs); 1759 1.2 matt } 1760 1.2 matt 1761 1.2 matt static bool 1762 1.2 matt pq3etsec_txq_fillable_p( 1763 1.2 matt struct pq3etsec_softc * const sc, 1764 1.2 matt struct pq3etsec_txqueue *txq) 1765 1.2 matt { 1766 1.2 matt return txq->txq_free >= txq->txq_threshold; 1767 1.2 matt } 1768 1.2 matt 1769 1.2 matt static int 1770 1.2 matt pq3etsec_txq_attach( 1771 1.2 matt struct pq3etsec_softc *sc, 1772 1.2 matt struct pq3etsec_txqueue *txq, 1773 1.2 matt u_int qno) 1774 1.2 matt { 1775 1.2 matt size_t map_size = PAGE_SIZE; 1776 1.2 matt size_t desc_count = map_size / sizeof(struct txbd); 1777 1.2 matt int error; 1778 1.2 matt void *descs; 1779 1.2 matt 1780 1.2 matt error = pq3etsec_dmamem_alloc(sc->sc_dmat, map_size, 1781 1.2 matt &txq->txq_descmap_seg, &txq->txq_descmap, &descs); 1782 1.2 matt if (error) 1783 1.2 matt return error; 1784 1.2 matt 1785 1.2 matt memset(descs, 0, map_size); 1786 1.2 matt txq->txq_first = descs; 1787 1.2 matt txq->txq_last = txq->txq_first + desc_count; 1788 1.2 matt txq->txq_consumer = descs; 1789 1.2 matt txq->txq_producer = descs; 1790 1.2 matt 1791 1.2 matt IFQ_SET_MAXLEN(&txq->txq_mbufs, ETSEC_MAXTXMBUFS); 1792 1.2 matt 1793 1.2 matt txq->txq_reg_tbase = TBASEn(qno); 1794 1.2 matt txq->txq_qmask = TSTAT_THLTn(qno) | TSTAT_TXFn(qno); 1795 1.2 matt 1796 1.2 matt pq3etsec_txq_reset(sc, txq); 1797 1.2 matt 1798 1.2 matt return 0; 1799 1.2 matt } 1800 1.2 matt 1801 1.2 matt static int 1802 1.2 matt pq3etsec_txq_map_load( 1803 1.2 matt struct pq3etsec_softc *sc, 1804 1.2 matt struct pq3etsec_txqueue *txq, 1805 1.2 matt struct mbuf *m) 1806 1.2 matt { 1807 1.2 matt bus_dmamap_t map; 1808 1.2 matt int error; 1809 1.2 matt 1810 1.2 matt map = M_GETCTX(m, bus_dmamap_t); 1811 1.2 matt if (map != NULL) 1812 1.2 matt return 0; 1813 1.2 matt 1814 1.2 matt map = pq3etsec_mapcache_get(sc, sc->sc_tx_mapcache); 1815 1.2 matt if (map == NULL) 1816 1.2 matt return ENOMEM; 1817 1.2 matt 1818 1.2 matt error = bus_dmamap_load_mbuf(sc->sc_dmat, map, m, 1819 1.2 matt BUS_DMA_WRITE | BUS_DMA_NOWAIT); 1820 1.2 matt if (error) 1821 1.2 matt return error; 1822 1.2 matt 1823 1.2 matt bus_dmamap_sync(sc->sc_dmat, map, 0, m->m_pkthdr.len, 1824 1.2 matt BUS_DMASYNC_PREWRITE); 1825 1.2 matt M_SETCTX(m, map); 1826 1.2 matt return 0; 1827 1.2 matt } 1828 1.2 matt 1829 1.2 matt static void 1830 1.2 matt pq3etsec_txq_map_unload( 1831 1.2 matt struct pq3etsec_softc *sc, 1832 1.2 matt struct pq3etsec_txqueue *txq, 1833 1.2 matt struct mbuf *m) 1834 1.2 matt { 1835 1.2 matt KASSERT(m); 1836 1.2 matt bus_dmamap_t map = M_GETCTX(m, bus_dmamap_t); 1837 1.2 matt bus_dmamap_sync(sc->sc_dmat, map, 0, map->dm_mapsize, 1838 1.2 matt BUS_DMASYNC_POSTWRITE); 1839 1.2 matt bus_dmamap_unload(sc->sc_dmat, map); 1840 1.2 matt pq3etsec_mapcache_put(sc, sc->sc_tx_mapcache, map); 1841 1.2 matt } 1842 1.2 matt 1843 1.2 matt static bool 1844 1.2 matt pq3etsec_txq_produce( 1845 1.2 matt struct pq3etsec_softc *sc, 1846 1.2 matt struct pq3etsec_txqueue *txq, 1847 1.2 matt struct mbuf *m) 1848 1.2 matt { 1849 1.2 matt bus_dmamap_t map = M_GETCTX(m, bus_dmamap_t); 1850 1.2 matt 1851 1.2 matt if (map->dm_nsegs > txq->txq_free) 1852 1.2 matt return false; 1853 1.2 matt 1854 1.2 matt /* 1855 1.2 matt * TCP Offload flag must be set in the first descriptor. 1856 1.2 matt */ 1857 1.2 matt volatile struct txbd *producer = txq->txq_producer; 1858 1.2 matt uint16_t last_flags = TXBD_L; 1859 1.2 matt uint16_t first_flags = TXBD_R 1860 1.2 matt | ((m->m_flags & M_HASFCB) ? TXBD_TOE : 0); 1861 1.2 matt 1862 1.2 matt /* 1863 1.2 matt * If we've produced enough descriptors without consuming any 1864 1.2 matt * we need to ask for an interrupt to reclaim some. 1865 1.2 matt */ 1866 1.2 matt txq->txq_lastintr += map->dm_nsegs; 1867 1.2 matt if (txq->txq_lastintr >= txq->txq_threshold 1868 1.2 matt || txq->txq_mbufs.ifq_len + 1 == txq->txq_mbufs.ifq_maxlen) { 1869 1.2 matt txq->txq_lastintr = 0; 1870 1.2 matt last_flags |= TXBD_I; 1871 1.2 matt } 1872 1.2 matt 1873 1.2 matt #ifdef ETSEC_DEBUG 1874 1.2 matt KASSERT(txq->txq_lmbufs[producer - txq->txq_first] == NULL); 1875 1.2 matt #endif 1876 1.2 matt KASSERT(producer != txq->txq_last); 1877 1.2 matt producer->txbd_bufptr = map->dm_segs[0].ds_addr; 1878 1.2 matt producer->txbd_len = map->dm_segs[0].ds_len; 1879 1.2 matt 1880 1.2 matt if (map->dm_nsegs > 1) { 1881 1.2 matt volatile struct txbd *start = producer + 1; 1882 1.2 matt size_t count = map->dm_nsegs - 1; 1883 1.2 matt for (u_int i = 1; i < map->dm_nsegs; i++) { 1884 1.2 matt if (__predict_false(++producer == txq->txq_last)) { 1885 1.2 matt producer = txq->txq_first; 1886 1.2 matt if (start < txq->txq_last) { 1887 1.2 matt pq3etsec_txq_desc_presync(sc, txq, 1888 1.2 matt start, txq->txq_last - start); 1889 1.2 matt count -= txq->txq_last - start; 1890 1.2 matt } 1891 1.2 matt start = txq->txq_first; 1892 1.2 matt } 1893 1.2 matt #ifdef ETSEC_DEBUG 1894 1.2 matt KASSERT(txq->txq_lmbufs[producer - txq->txq_first] == NULL); 1895 1.2 matt #endif 1896 1.2 matt producer->txbd_bufptr = map->dm_segs[i].ds_addr; 1897 1.2 matt producer->txbd_len = map->dm_segs[i].ds_len; 1898 1.2 matt producer->txbd_flags = TXBD_R 1899 1.2 matt | (producer->txbd_flags & TXBD_W) 1900 1.2 matt | (i == map->dm_nsegs - 1 ? last_flags : 0); 1901 1.2 matt #if 0 1902 1.2 matt printf("%s: txbd[%u]=%#x/%u/%#x\n", __func__, producer - txq->txq_first, 1903 1.2 matt producer->txbd_flags, producer->txbd_len, producer->txbd_bufptr); 1904 1.2 matt #endif 1905 1.2 matt } 1906 1.2 matt pq3etsec_txq_desc_presync(sc, txq, start, count); 1907 1.2 matt } else { 1908 1.2 matt first_flags |= last_flags; 1909 1.2 matt } 1910 1.2 matt 1911 1.2 matt membar_producer(); 1912 1.2 matt txq->txq_producer->txbd_flags = 1913 1.2 matt first_flags | (txq->txq_producer->txbd_flags & TXBD_W); 1914 1.2 matt #if 0 1915 1.2 matt printf("%s: txbd[%u]=%#x/%u/%#x\n", __func__, 1916 1.2 matt txq->txq_producer - txq->txq_first, txq->txq_producer->txbd_flags, 1917 1.2 matt txq->txq_producer->txbd_len, txq->txq_producer->txbd_bufptr); 1918 1.2 matt #endif 1919 1.2 matt pq3etsec_txq_desc_presync(sc, txq, txq->txq_producer, 1); 1920 1.2 matt 1921 1.2 matt /* 1922 1.2 matt * Reduce free count by the number of segments we consumed. 1923 1.2 matt */ 1924 1.2 matt txq->txq_free -= map->dm_nsegs; 1925 1.2 matt KASSERT(map->dm_nsegs == 1 || txq->txq_producer != producer); 1926 1.2 matt KASSERT(map->dm_nsegs == 1 || (txq->txq_producer->txbd_flags & TXBD_L) == 0); 1927 1.2 matt KASSERT(producer->txbd_flags & TXBD_L); 1928 1.2 matt #ifdef ETSEC_DEBUG 1929 1.2 matt txq->txq_lmbufs[producer - txq->txq_first] = m; 1930 1.2 matt #endif 1931 1.2 matt 1932 1.2 matt #if 0 1933 1.2 matt printf("%s: mbuf %p: produced a %u byte packet in %u segments (%u..%u)\n", 1934 1.2 matt __func__, m, m->m_pkthdr.len, map->dm_nsegs, 1935 1.2 matt txq->txq_producer - txq->txq_first, producer - txq->txq_first); 1936 1.2 matt #endif 1937 1.2 matt 1938 1.2 matt if (++producer == txq->txq_last) 1939 1.2 matt txq->txq_producer = txq->txq_first; 1940 1.2 matt else 1941 1.2 matt txq->txq_producer = producer; 1942 1.2 matt IF_ENQUEUE(&txq->txq_mbufs, m); 1943 1.2 matt 1944 1.2 matt /* 1945 1.2 matt * Restart the transmitter. 1946 1.2 matt */ 1947 1.2 matt etsec_write(sc, TSTAT, txq->txq_qmask & TSTAT_THLT); /* W1C */ 1948 1.2 matt 1949 1.2 matt return true; 1950 1.2 matt } 1951 1.2 matt 1952 1.2 matt static void 1953 1.2 matt pq3etsec_tx_offload( 1954 1.2 matt struct pq3etsec_softc *sc, 1955 1.2 matt struct pq3etsec_txqueue *txq, 1956 1.2 matt struct mbuf **mp) 1957 1.2 matt { 1958 1.2 matt struct mbuf *m = *mp; 1959 1.2 matt u_int csum_flags = m->m_pkthdr.csum_flags; 1960 1.2 matt struct m_tag *vtag = VLAN_OUTPUT_TAG(&sc->sc_ec, m); 1961 1.2 matt 1962 1.2 matt KASSERT(m->m_flags & M_PKTHDR); 1963 1.2 matt 1964 1.2 matt /* 1965 1.2 matt * Let see if we are doing any offload first. 1966 1.2 matt */ 1967 1.2 matt if (csum_flags == 0 && vtag == 0) { 1968 1.2 matt m->m_flags &= ~M_HASFCB; 1969 1.2 matt return; 1970 1.2 matt } 1971 1.2 matt 1972 1.2 matt uint16_t flags = 0; 1973 1.2 matt if (csum_flags & M_CSUM_IP) { 1974 1.2 matt flags |= TXFCB_IP 1975 1.2 matt | ((csum_flags & M_CSUM_IP6) ? TXFCB_IP6 : 0) 1976 1.2 matt | ((csum_flags & M_CSUM_TUP) ? TXFCB_TUP : 0) 1977 1.2 matt | ((csum_flags & M_CSUM_UDP) ? TXFCB_UDP : 0) 1978 1.2 matt | ((csum_flags & M_CSUM_CIP) ? TXFCB_CIP : 0) 1979 1.2 matt | ((csum_flags & M_CSUM_CTU) ? TXFCB_CTU : 0); 1980 1.2 matt } 1981 1.2 matt if (vtag) { 1982 1.2 matt flags |= TXFCB_VLN; 1983 1.2 matt } 1984 1.2 matt if (flags == 0) { 1985 1.2 matt m->m_flags &= ~M_HASFCB; 1986 1.2 matt return; 1987 1.2 matt } 1988 1.2 matt 1989 1.2 matt struct txfcb fcb; 1990 1.2 matt fcb.txfcb_flags = flags; 1991 1.2 matt if (csum_flags & M_CSUM_IPv4) 1992 1.2 matt fcb.txfcb_l4os = M_CSUM_DATA_IPv4_IPHL(m->m_pkthdr.csum_data); 1993 1.2 matt else 1994 1.2 matt fcb.txfcb_l4os = M_CSUM_DATA_IPv6_HL(m->m_pkthdr.csum_data); 1995 1.2 matt fcb.txfcb_l3os = ETHER_HDR_LEN; 1996 1.2 matt fcb.txfcb_phcs = 0; 1997 1.2 matt fcb.txfcb_vlctl = vtag ? VLAN_TAG_VALUE(vtag) & 0xffff : 0; 1998 1.2 matt 1999 1.2 matt #if 0 2000 1.2 matt printf("%s: csum_flags=%#x: txfcb flags=%#x lsos=%u l4os=%u phcs=%u vlctl=%#x\n", 2001 1.2 matt __func__, csum_flags, fcb.txfcb_flags, fcb.txfcb_l3os, fcb.txfcb_l4os, 2002 1.2 matt fcb.txfcb_phcs, fcb.txfcb_vlctl); 2003 1.2 matt #endif 2004 1.2 matt 2005 1.2 matt if (M_LEADINGSPACE(m) >= sizeof(fcb)) { 2006 1.2 matt m->m_data -= sizeof(fcb); 2007 1.2 matt m->m_len += sizeof(fcb); 2008 1.2 matt } else if (!(m->m_flags & M_EXT) && MHLEN - m->m_len >= sizeof(fcb)) { 2009 1.2 matt memmove(m->m_pktdat + sizeof(fcb), m->m_data, m->m_len); 2010 1.2 matt m->m_data = m->m_pktdat; 2011 1.2 matt m->m_len += sizeof(fcb); 2012 1.2 matt } else { 2013 1.2 matt struct mbuf *mn; 2014 1.2 matt MGET(mn, M_DONTWAIT, m->m_type); 2015 1.2 matt if (mn == NULL) { 2016 1.2 matt if (csum_flags & M_CSUM_IP4) { 2017 1.2 matt #ifdef INET 2018 1.2 matt ip_undefer_csum(m, ETHER_HDR_LEN, 2019 1.2 matt csum_flags & M_CSUM_IP4); 2020 1.2 matt #else 2021 1.2 matt panic("%s: impossible M_CSUM flags %#x", 2022 1.2 matt device_xname(sc->sc_dev), csum_flags); 2023 1.2 matt #endif 2024 1.2 matt } else if (csum_flags & M_CSUM_IP6) { 2025 1.2 matt #ifdef INET6 2026 1.2 matt ip6_undefer_csum(m, ETHER_HDR_LEN, 2027 1.2 matt csum_flags & M_CSUM_IP6); 2028 1.2 matt #else 2029 1.2 matt panic("%s: impossible M_CSUM flags %#x", 2030 1.2 matt device_xname(sc->sc_dev), csum_flags); 2031 1.2 matt #endif 2032 1.2 matt } else if (vtag) { 2033 1.2 matt } 2034 1.2 matt 2035 1.2 matt m->m_flags &= ~M_HASFCB; 2036 1.2 matt return; 2037 1.2 matt } 2038 1.2 matt 2039 1.2 matt M_MOVE_PKTHDR(mn, m); 2040 1.2 matt mn->m_next = m; 2041 1.2 matt m = mn; 2042 1.2 matt MH_ALIGN(m, sizeof(fcb)); 2043 1.2 matt m->m_len = sizeof(fcb); 2044 1.2 matt *mp = m; 2045 1.2 matt } 2046 1.2 matt m->m_pkthdr.len += sizeof(fcb); 2047 1.2 matt m->m_flags |= M_HASFCB; 2048 1.2 matt *mtod(m, struct txfcb *) = fcb; 2049 1.2 matt return; 2050 1.2 matt } 2051 1.2 matt 2052 1.2 matt static bool 2053 1.2 matt pq3etsec_txq_enqueue( 2054 1.2 matt struct pq3etsec_softc *sc, 2055 1.2 matt struct pq3etsec_txqueue *txq) 2056 1.2 matt { 2057 1.2 matt for (;;) { 2058 1.2 matt if (IF_QFULL(&txq->txq_mbufs)) 2059 1.2 matt return false; 2060 1.2 matt struct mbuf *m = txq->txq_next; 2061 1.2 matt if (m == NULL) { 2062 1.2 matt int s = splnet(); 2063 1.20 nonaka IFQ_DEQUEUE(&sc->sc_if.if_snd, m); 2064 1.2 matt splx(s); 2065 1.2 matt if (m == NULL) 2066 1.2 matt return true; 2067 1.2 matt M_SETCTX(m, NULL); 2068 1.2 matt pq3etsec_tx_offload(sc, txq, &m); 2069 1.2 matt } else { 2070 1.2 matt txq->txq_next = NULL; 2071 1.2 matt } 2072 1.2 matt int error = pq3etsec_txq_map_load(sc, txq, m); 2073 1.2 matt if (error) { 2074 1.2 matt aprint_error_dev(sc->sc_dev, 2075 1.2 matt "discarded packet due to " 2076 1.2 matt "dmamap load failure: %d\n", error); 2077 1.2 matt m_freem(m); 2078 1.2 matt continue; 2079 1.2 matt } 2080 1.2 matt KASSERT(txq->txq_next == NULL); 2081 1.2 matt if (!pq3etsec_txq_produce(sc, txq, m)) { 2082 1.2 matt txq->txq_next = m; 2083 1.2 matt return false; 2084 1.2 matt } 2085 1.2 matt KASSERT(txq->txq_next == NULL); 2086 1.2 matt } 2087 1.2 matt } 2088 1.2 matt 2089 1.2 matt static bool 2090 1.2 matt pq3etsec_txq_consume( 2091 1.2 matt struct pq3etsec_softc *sc, 2092 1.2 matt struct pq3etsec_txqueue *txq) 2093 1.2 matt { 2094 1.2 matt struct ifnet * const ifp = &sc->sc_if; 2095 1.2 matt volatile struct txbd *consumer = txq->txq_consumer; 2096 1.2 matt size_t txfree = 0; 2097 1.2 matt 2098 1.2 matt #if 0 2099 1.2 matt printf("%s: entry: free=%zu\n", __func__, txq->txq_free); 2100 1.2 matt #endif 2101 1.2 matt etsec_write(sc, TSTAT, TSTAT_TXF & txq->txq_qmask); 2102 1.2 matt 2103 1.2 matt for (;;) { 2104 1.2 matt if (consumer == txq->txq_producer) { 2105 1.2 matt txq->txq_consumer = consumer; 2106 1.2 matt txq->txq_free += txfree; 2107 1.2 matt txq->txq_lastintr -= min(txq->txq_lastintr, txfree); 2108 1.2 matt #if 0 2109 1.2 matt printf("%s: empty: freed %zu descriptors going form %zu to %zu\n", 2110 1.2 matt __func__, txfree, txq->txq_free - txfree, txq->txq_free); 2111 1.2 matt #endif 2112 1.2 matt KASSERT(txq->txq_lastintr == 0); 2113 1.2 matt KASSERT(txq->txq_free == txq->txq_last - txq->txq_first - 1); 2114 1.2 matt return true; 2115 1.2 matt } 2116 1.2 matt pq3etsec_txq_desc_postsync(sc, txq, consumer, 1); 2117 1.2 matt const uint16_t txbd_flags = consumer->txbd_flags; 2118 1.2 matt if (txbd_flags & TXBD_R) { 2119 1.2 matt txq->txq_consumer = consumer; 2120 1.2 matt txq->txq_free += txfree; 2121 1.2 matt txq->txq_lastintr -= min(txq->txq_lastintr, txfree); 2122 1.2 matt #if 0 2123 1.2 matt printf("%s: freed %zu descriptors\n", 2124 1.2 matt __func__, txfree); 2125 1.2 matt #endif 2126 1.2 matt return pq3etsec_txq_fillable_p(sc, txq); 2127 1.2 matt } 2128 1.2 matt 2129 1.2 matt /* 2130 1.2 matt * If this is the last descriptor in the chain, get the 2131 1.2 matt * mbuf, free its dmamap, and free the mbuf chain itself. 2132 1.2 matt */ 2133 1.2 matt if (txbd_flags & TXBD_L) { 2134 1.2 matt struct mbuf *m; 2135 1.2 matt 2136 1.2 matt IF_DEQUEUE(&txq->txq_mbufs, m); 2137 1.2 matt #ifdef ETSEC_DEBUG 2138 1.8 jym KASSERTMSG( 2139 1.8 jym m == txq->txq_lmbufs[consumer-txq->txq_first], 2140 1.8 jym "%s: %p [%u]: flags %#x m (%p) != %p (%p)", 2141 1.8 jym __func__, consumer, consumer - txq->txq_first, 2142 1.8 jym txbd_flags, m, 2143 1.8 jym &txq->txq_lmbufs[consumer-txq->txq_first], 2144 1.8 jym txq->txq_lmbufs[consumer-txq->txq_first]); 2145 1.2 matt #endif 2146 1.2 matt KASSERT(m); 2147 1.2 matt pq3etsec_txq_map_unload(sc, txq, m); 2148 1.2 matt #if 0 2149 1.2 matt printf("%s: mbuf %p: consumed a %u byte packet\n", 2150 1.2 matt __func__, m, m->m_pkthdr.len); 2151 1.2 matt #endif 2152 1.2 matt if (m->m_flags & M_HASFCB) 2153 1.2 matt m_adj(m, sizeof(struct txfcb)); 2154 1.2 matt ifp->if_opackets++; 2155 1.2 matt ifp->if_obytes += m->m_pkthdr.len; 2156 1.2 matt if (m->m_flags & M_MCAST) 2157 1.2 matt ifp->if_omcasts++; 2158 1.2 matt if (txbd_flags & TXBD_ERRORS) 2159 1.2 matt ifp->if_oerrors++; 2160 1.2 matt m_freem(m); 2161 1.2 matt #ifdef ETSEC_DEBUG 2162 1.2 matt txq->txq_lmbufs[consumer - txq->txq_first] = NULL; 2163 1.2 matt #endif 2164 1.2 matt } else { 2165 1.2 matt #ifdef ETSEC_DEBUG 2166 1.2 matt KASSERT(txq->txq_lmbufs[consumer-txq->txq_first] == NULL); 2167 1.2 matt #endif 2168 1.2 matt } 2169 1.2 matt 2170 1.2 matt /* 2171 1.2 matt * We own this packet again. Clear all flags except wrap. 2172 1.2 matt */ 2173 1.2 matt txfree++; 2174 1.2 matt //consumer->txbd_flags = txbd_flags & TXBD_W; 2175 1.2 matt 2176 1.2 matt /* 2177 1.2 matt * Wrap at the last entry! 2178 1.2 matt */ 2179 1.2 matt if (txbd_flags & TXBD_W) { 2180 1.2 matt KASSERT(consumer + 1 == txq->txq_last); 2181 1.2 matt consumer = txq->txq_first; 2182 1.2 matt } else { 2183 1.2 matt consumer++; 2184 1.2 matt KASSERT(consumer < txq->txq_last); 2185 1.2 matt } 2186 1.2 matt } 2187 1.2 matt } 2188 1.2 matt 2189 1.2 matt static void 2190 1.2 matt pq3etsec_txq_purge( 2191 1.2 matt struct pq3etsec_softc *sc, 2192 1.2 matt struct pq3etsec_txqueue *txq) 2193 1.2 matt { 2194 1.2 matt struct mbuf *m; 2195 1.2 matt KASSERT((etsec_read(sc, MACCFG1) & MACCFG1_TX_EN) == 0); 2196 1.2 matt 2197 1.2 matt for (;;) { 2198 1.2 matt IF_DEQUEUE(&txq->txq_mbufs, m); 2199 1.2 matt if (m == NULL) 2200 1.2 matt break; 2201 1.2 matt pq3etsec_txq_map_unload(sc, txq, m); 2202 1.2 matt m_freem(m); 2203 1.2 matt } 2204 1.2 matt if ((m = txq->txq_next) != NULL) { 2205 1.2 matt txq->txq_next = NULL; 2206 1.2 matt pq3etsec_txq_map_unload(sc, txq, m); 2207 1.2 matt m_freem(m); 2208 1.2 matt } 2209 1.2 matt #ifdef ETSEC_DEBUG 2210 1.2 matt memset(txq->txq_lmbufs, 0, sizeof(txq->txq_lmbufs)); 2211 1.2 matt #endif 2212 1.2 matt } 2213 1.2 matt 2214 1.2 matt static void 2215 1.2 matt pq3etsec_txq_reset( 2216 1.2 matt struct pq3etsec_softc *sc, 2217 1.2 matt struct pq3etsec_txqueue *txq) 2218 1.2 matt { 2219 1.2 matt /* 2220 1.2 matt * sync all the descriptors 2221 1.2 matt */ 2222 1.2 matt pq3etsec_txq_desc_postsync(sc, txq, txq->txq_first, 2223 1.2 matt txq->txq_last - txq->txq_first); 2224 1.2 matt 2225 1.2 matt /* 2226 1.2 matt * Make sure we own all descriptors in the ring. 2227 1.2 matt */ 2228 1.2 matt volatile struct txbd *txbd; 2229 1.2 matt for (txbd = txq->txq_first; txbd < txq->txq_last - 1; txbd++) { 2230 1.2 matt txbd->txbd_flags = 0; 2231 1.2 matt } 2232 1.2 matt 2233 1.2 matt /* 2234 1.2 matt * Last descriptor has the wrap flag. 2235 1.2 matt */ 2236 1.2 matt txbd->txbd_flags = TXBD_W; 2237 1.2 matt 2238 1.2 matt /* 2239 1.2 matt * Reset the producer consumer indexes. 2240 1.2 matt */ 2241 1.2 matt txq->txq_consumer = txq->txq_first; 2242 1.2 matt txq->txq_producer = txq->txq_first; 2243 1.2 matt txq->txq_free = txq->txq_last - txq->txq_first - 1; 2244 1.2 matt txq->txq_threshold = txq->txq_free / 2; 2245 1.2 matt txq->txq_lastintr = 0; 2246 1.2 matt 2247 1.2 matt /* 2248 1.2 matt * What do we want to get interrupted on? 2249 1.2 matt */ 2250 1.2 matt sc->sc_imask |= IEVENT_TXF|IEVENT_TXE; 2251 1.2 matt 2252 1.2 matt /* 2253 1.2 matt * Restart the transmit at the first descriptor 2254 1.2 matt */ 2255 1.2 matt etsec_write(sc, txq->txq_reg_tbase, txq->txq_descmap->dm_segs->ds_addr); 2256 1.2 matt } 2257 1.2 matt 2258 1.2 matt static void 2259 1.2 matt pq3etsec_ifstart(struct ifnet *ifp) 2260 1.2 matt { 2261 1.2 matt struct pq3etsec_softc * const sc = ifp->if_softc; 2262 1.2 matt 2263 1.2 matt atomic_or_uint(&sc->sc_soft_flags, SOFT_TXINTR); 2264 1.2 matt softint_schedule(sc->sc_soft_ih); 2265 1.2 matt } 2266 1.2 matt 2267 1.2 matt static void 2268 1.2 matt pq3etsec_tx_error( 2269 1.2 matt struct pq3etsec_softc * const sc) 2270 1.2 matt { 2271 1.2 matt struct pq3etsec_txqueue * const txq = &sc->sc_txq; 2272 1.2 matt 2273 1.2 matt pq3etsec_txq_consume(sc, txq); 2274 1.2 matt 2275 1.2 matt if (pq3etsec_txq_fillable_p(sc, txq)) 2276 1.2 matt sc->sc_if.if_flags &= ~IFF_OACTIVE; 2277 1.2 matt if (sc->sc_txerrors & (IEVENT_LC|IEVENT_CRL|IEVENT_XFUN|IEVENT_BABT)) { 2278 1.2 matt } else if (sc->sc_txerrors & IEVENT_EBERR) { 2279 1.2 matt } 2280 1.2 matt 2281 1.2 matt if (pq3etsec_txq_active_p(sc, txq)) 2282 1.2 matt etsec_write(sc, TSTAT, TSTAT_THLT & txq->txq_qmask); 2283 1.2 matt if (!pq3etsec_txq_enqueue(sc, txq)) { 2284 1.2 matt sc->sc_ev_tx_stall.ev_count++; 2285 1.2 matt sc->sc_if.if_flags |= IFF_OACTIVE; 2286 1.2 matt } 2287 1.2 matt 2288 1.2 matt sc->sc_txerrors = 0; 2289 1.2 matt } 2290 1.2 matt 2291 1.2 matt int 2292 1.2 matt pq3etsec_tx_intr(void *arg) 2293 1.2 matt { 2294 1.2 matt struct pq3etsec_softc * const sc = arg; 2295 1.2 matt 2296 1.2 matt sc->sc_ev_tx_intr.ev_count++; 2297 1.2 matt 2298 1.2 matt uint32_t ievent = etsec_read(sc, IEVENT); 2299 1.2 matt ievent &= IEVENT_TXF|IEVENT_TXB; 2300 1.2 matt etsec_write(sc, IEVENT, ievent); /* write 1 to clear */ 2301 1.2 matt 2302 1.2 matt #if 0 2303 1.2 matt aprint_normal_dev(sc->sc_dev, "%s: ievent=%#x imask=%#x\n", 2304 1.2 matt __func__, ievent, etsec_read(sc, IMASK)); 2305 1.2 matt #endif 2306 1.2 matt 2307 1.2 matt if (ievent == 0) 2308 1.2 matt return 0; 2309 1.2 matt 2310 1.2 matt sc->sc_imask &= ~(IEVENT_TXF|IEVENT_TXB); 2311 1.2 matt atomic_or_uint(&sc->sc_soft_flags, SOFT_TXINTR); 2312 1.2 matt etsec_write(sc, IMASK, sc->sc_imask); 2313 1.2 matt softint_schedule(sc->sc_soft_ih); 2314 1.2 matt return 1; 2315 1.2 matt } 2316 1.2 matt 2317 1.2 matt int 2318 1.2 matt pq3etsec_rx_intr(void *arg) 2319 1.2 matt { 2320 1.2 matt struct pq3etsec_softc * const sc = arg; 2321 1.2 matt 2322 1.2 matt sc->sc_ev_rx_intr.ev_count++; 2323 1.2 matt 2324 1.2 matt uint32_t ievent = etsec_read(sc, IEVENT); 2325 1.2 matt ievent &= IEVENT_RXF|IEVENT_RXB; 2326 1.2 matt etsec_write(sc, IEVENT, ievent); /* write 1 to clear */ 2327 1.2 matt if (ievent == 0) 2328 1.2 matt return 0; 2329 1.2 matt 2330 1.2 matt #if 0 2331 1.2 matt aprint_normal_dev(sc->sc_dev, "%s: ievent=%#x\n", __func__, ievent); 2332 1.2 matt #endif 2333 1.2 matt 2334 1.2 matt sc->sc_imask &= ~(IEVENT_RXF|IEVENT_RXB); 2335 1.2 matt atomic_or_uint(&sc->sc_soft_flags, SOFT_RXINTR); 2336 1.2 matt etsec_write(sc, IMASK, sc->sc_imask); 2337 1.2 matt softint_schedule(sc->sc_soft_ih); 2338 1.2 matt return 1; 2339 1.2 matt } 2340 1.2 matt 2341 1.2 matt int 2342 1.2 matt pq3etsec_error_intr(void *arg) 2343 1.2 matt { 2344 1.2 matt struct pq3etsec_softc * const sc = arg; 2345 1.2 matt 2346 1.2 matt sc->sc_ev_error_intr.ev_count++; 2347 1.2 matt 2348 1.2 matt for (int rv = 0, soft_flags = 0;; rv = 1) { 2349 1.2 matt uint32_t ievent = etsec_read(sc, IEVENT); 2350 1.2 matt ievent &= ~(IEVENT_RXF|IEVENT_RXB|IEVENT_TXF|IEVENT_TXB); 2351 1.2 matt etsec_write(sc, IEVENT, ievent); /* write 1 to clear */ 2352 1.2 matt if (ievent == 0) { 2353 1.2 matt if (soft_flags) { 2354 1.2 matt atomic_or_uint(&sc->sc_soft_flags, soft_flags); 2355 1.2 matt softint_schedule(sc->sc_soft_ih); 2356 1.2 matt } 2357 1.2 matt return rv; 2358 1.2 matt } 2359 1.2 matt #if 0 2360 1.2 matt aprint_normal_dev(sc->sc_dev, "%s: ievent=%#x imask=%#x\n", 2361 1.2 matt __func__, ievent, etsec_read(sc, IMASK)); 2362 1.2 matt #endif 2363 1.2 matt 2364 1.2 matt if (ievent & (IEVENT_GRSC|IEVENT_GTSC)) { 2365 1.2 matt sc->sc_imask &= ~(IEVENT_GRSC|IEVENT_GTSC); 2366 1.2 matt etsec_write(sc, IMASK, sc->sc_imask); 2367 1.2 matt wakeup(sc); 2368 1.2 matt } 2369 1.2 matt if (ievent & (IEVENT_MMRD|IEVENT_MMWR)) { 2370 1.2 matt sc->sc_imask &= ~(IEVENT_MMRD|IEVENT_MMWR); 2371 1.2 matt etsec_write(sc, IMASK, sc->sc_imask); 2372 1.2 matt wakeup(&sc->sc_mii); 2373 1.2 matt } 2374 1.2 matt if (ievent & IEVENT_BSY) { 2375 1.2 matt soft_flags |= SOFT_RXBSY; 2376 1.2 matt sc->sc_imask &= ~IEVENT_BSY; 2377 1.2 matt etsec_write(sc, IMASK, sc->sc_imask); 2378 1.2 matt } 2379 1.2 matt if (ievent & IEVENT_TXE) { 2380 1.2 matt soft_flags |= SOFT_TXERROR; 2381 1.2 matt sc->sc_imask &= ~IEVENT_TXE; 2382 1.2 matt sc->sc_txerrors |= ievent; 2383 1.2 matt } 2384 1.2 matt if (ievent & IEVENT_TXC) { 2385 1.2 matt sc->sc_ev_tx_pause.ev_count++; 2386 1.2 matt } 2387 1.2 matt if (ievent & IEVENT_RXC) { 2388 1.2 matt sc->sc_ev_rx_pause.ev_count++; 2389 1.2 matt } 2390 1.2 matt if (ievent & IEVENT_DPE) { 2391 1.2 matt soft_flags |= SOFT_RESET; 2392 1.2 matt sc->sc_imask &= ~IEVENT_DPE; 2393 1.2 matt etsec_write(sc, IMASK, sc->sc_imask); 2394 1.2 matt } 2395 1.2 matt } 2396 1.2 matt } 2397 1.2 matt 2398 1.2 matt void 2399 1.2 matt pq3etsec_soft_intr(void *arg) 2400 1.2 matt { 2401 1.2 matt struct pq3etsec_softc * const sc = arg; 2402 1.2 matt struct ifnet * const ifp = &sc->sc_if; 2403 1.2 matt 2404 1.2 matt mutex_enter(sc->sc_lock); 2405 1.2 matt 2406 1.2 matt u_int soft_flags = atomic_swap_uint(&sc->sc_soft_flags, 0); 2407 1.2 matt 2408 1.2 matt sc->sc_ev_soft_intr.ev_count++; 2409 1.2 matt 2410 1.2 matt if (soft_flags & SOFT_RESET) { 2411 1.2 matt int s = splnet(); 2412 1.2 matt pq3etsec_ifinit(ifp); 2413 1.2 matt splx(s); 2414 1.2 matt soft_flags = 0; 2415 1.2 matt } 2416 1.2 matt 2417 1.2 matt if (soft_flags & SOFT_RXBSY) { 2418 1.2 matt struct pq3etsec_rxqueue * const rxq = &sc->sc_rxq; 2419 1.2 matt size_t threshold = 5 * rxq->rxq_threshold / 4; 2420 1.2 matt if (threshold >= rxq->rxq_last - rxq->rxq_first) { 2421 1.2 matt threshold = rxq->rxq_last - rxq->rxq_first - 1; 2422 1.2 matt } else { 2423 1.2 matt sc->sc_imask |= IEVENT_BSY; 2424 1.2 matt } 2425 1.2 matt aprint_normal_dev(sc->sc_dev, 2426 1.2 matt "increasing receive buffers from %zu to %zu\n", 2427 1.2 matt rxq->rxq_threshold, threshold); 2428 1.2 matt rxq->rxq_threshold = threshold; 2429 1.2 matt } 2430 1.2 matt 2431 1.2 matt if ((soft_flags & SOFT_TXINTR) 2432 1.2 matt || pq3etsec_txq_active_p(sc, &sc->sc_txq)) { 2433 1.2 matt /* 2434 1.2 matt * Let's do what we came here for. Consume transmitted 2435 1.2 matt * packets off the the transmit ring. 2436 1.2 matt */ 2437 1.2 matt if (!pq3etsec_txq_consume(sc, &sc->sc_txq) 2438 1.2 matt || !pq3etsec_txq_enqueue(sc, &sc->sc_txq)) { 2439 1.2 matt sc->sc_ev_tx_stall.ev_count++; 2440 1.2 matt ifp->if_flags |= IFF_OACTIVE; 2441 1.2 matt } else { 2442 1.2 matt ifp->if_flags &= ~IFF_OACTIVE; 2443 1.2 matt } 2444 1.2 matt sc->sc_imask |= IEVENT_TXF; 2445 1.2 matt } 2446 1.2 matt 2447 1.2 matt if (soft_flags & (SOFT_RXINTR|SOFT_RXBSY)) { 2448 1.2 matt /* 2449 1.2 matt * Let's consume 2450 1.2 matt */ 2451 1.2 matt pq3etsec_rxq_consume(sc, &sc->sc_rxq); 2452 1.2 matt sc->sc_imask |= IEVENT_RXF; 2453 1.2 matt } 2454 1.2 matt 2455 1.2 matt if (soft_flags & SOFT_TXERROR) { 2456 1.2 matt pq3etsec_tx_error(sc); 2457 1.2 matt sc->sc_imask |= IEVENT_TXE; 2458 1.2 matt } 2459 1.2 matt 2460 1.2 matt if (ifp->if_flags & IFF_RUNNING) { 2461 1.2 matt pq3etsec_rxq_produce(sc, &sc->sc_rxq); 2462 1.2 matt etsec_write(sc, IMASK, sc->sc_imask); 2463 1.2 matt } else { 2464 1.2 matt KASSERT((soft_flags & SOFT_RXBSY) == 0); 2465 1.2 matt } 2466 1.2 matt 2467 1.2 matt mutex_exit(sc->sc_lock); 2468 1.2 matt } 2469 1.2 matt 2470 1.2 matt static void 2471 1.2 matt pq3etsec_mii_tick(void *arg) 2472 1.2 matt { 2473 1.2 matt struct pq3etsec_softc * const sc = arg; 2474 1.2 matt mutex_enter(sc->sc_lock); 2475 1.2 matt callout_ack(&sc->sc_mii_callout); 2476 1.2 matt sc->sc_ev_mii_ticks.ev_count++; 2477 1.2 matt #ifdef DEBUG 2478 1.2 matt uint64_t now = mftb(); 2479 1.2 matt if (now - sc->sc_mii_last_tick < cpu_timebase - 5000) { 2480 1.2 matt aprint_debug_dev(sc->sc_dev, "%s: diff=%"PRIu64"\n", 2481 1.2 matt __func__, now - sc->sc_mii_last_tick); 2482 1.2 matt callout_stop(&sc->sc_mii_callout); 2483 1.2 matt } 2484 1.2 matt #endif 2485 1.2 matt mii_tick(&sc->sc_mii); 2486 1.2 matt int s = splnet(); 2487 1.2 matt if (sc->sc_soft_flags & SOFT_RESET) 2488 1.2 matt softint_schedule(sc->sc_soft_ih); 2489 1.2 matt splx(s); 2490 1.2 matt callout_schedule(&sc->sc_mii_callout, hz); 2491 1.6 matt #ifdef DEBUG 2492 1.2 matt sc->sc_mii_last_tick = now; 2493 1.6 matt #endif 2494 1.2 matt mutex_exit(sc->sc_lock); 2495 1.2 matt } 2496
Indexes created Mon Sep 29 21:09:56 GMT 2025