1 /*- 2 * Copyright (c) 2006-2007 Broadcom Corporation 3 * David Christensen <davidch@broadcom.com>. All rights reserved. 4 * 5 * Redistribution and use in source and binary forms, with or without 6 * modification, are permitted provided that the following conditions 7 * are met: 8 * 9 * 1. Redistributions of source code must retain the above copyright 10 * notice, this list of conditions and the following disclaimer. 11 * 2. Redistributions in binary form must reproduce the above copyright 12 * notice, this list of conditions and the following disclaimer in the 13 * documentation and/or other materials provided with the distribution. 14 * 3. Neither the name of Broadcom Corporation nor the name of its contributors 15 * may be used to endorse or promote products derived from this software 16 * without specific prior written consent. 17 * 18 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS' 19 * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 20 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 21 * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS 22 * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 23 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 24 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 25 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 26 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 27 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF 28 * THE POSSIBILITY OF SUCH DAMAGE. 29 * 30 * $FreeBSD: src/sys/dev/bce/if_bce.c,v 1.31 2007/05/16 23:34:11 davidch Exp $ 31 */ 32 33 /* 34 * The following controllers are supported by this driver: 35 * BCM5706C A2, A3 36 * BCM5706S A2, A3 37 * BCM5708C B1, B2 38 * BCM5708S B1, B2 39 * BCM5709C A1, B2, C0 40 * BCM5716 C0 41 * 42 * The following controllers are not supported by this driver: 43 * BCM5706C A0, A1 44 * BCM5706S A0, A1 45 * BCM5708C A0, B0 46 * BCM5708S A0, B0 47 * BCM5709C A0, B0, B1 48 * BCM5709S A0, A1, B0, B1, B2, C0 49 * 50 * 51 * Note about MSI-X on 5709/5716: 52 * - 9 MSI-X vectors are supported. 53 * - MSI-X vectors, RX/TX rings and status blocks' association 54 * are fixed: 55 * o The first RX ring and the first TX ring use the first 56 * status block. 57 * o The first MSI-X vector is associated with the first 58 * status block. 59 * o The second RX ring and the second TX ring use the second 60 * status block. 61 * o The second MSI-X vector is associated with the second 62 * status block. 63 * ... 64 * and so on so forth. 65 * - Status blocks must reside in physically contiguous memory 66 * and each status block consumes 128bytes. In addition to 67 * this, the memory for the status blocks is aligned on 128bytes 68 * in this driver. (see bce_dma_alloc() and HC_CONFIG) 69 * - Each status block has its own coalesce parameters, which also 70 * serve as the related MSI-X vector's interrupt moderation 71 * parameters. (see bce_coal_change()) 72 */ 73 74 #include "opt_bce.h" 75 #include "opt_ifpoll.h" 76 77 #include <sys/param.h> 78 #include <sys/bus.h> 79 #include <sys/endian.h> 80 #include <sys/kernel.h> 81 #include <sys/interrupt.h> 82 #include <sys/mbuf.h> 83 #include <sys/malloc.h> 84 #include <sys/queue.h> 85 #include <sys/rman.h> 86 #include <sys/serialize.h> 87 #include <sys/socket.h> 88 #include <sys/sockio.h> 89 #include <sys/sysctl.h> 90 91 #include <netinet/ip.h> 92 #include <netinet/tcp.h> 93 94 #include <net/bpf.h> 95 #include <net/ethernet.h> 96 #include <net/if.h> 97 #include <net/if_arp.h> 98 #include <net/if_dl.h> 99 #include <net/if_media.h> 100 #include <net/if_poll.h> 101 #include <net/if_types.h> 102 #include <net/ifq_var.h> 103 #include <net/toeplitz.h> 104 #include <net/toeplitz2.h> 105 #include <net/vlan/if_vlan_var.h> 106 #include <net/vlan/if_vlan_ether.h> 107 108 #include <dev/netif/mii_layer/mii.h> 109 #include <dev/netif/mii_layer/miivar.h> 110 #include <dev/netif/mii_layer/brgphyreg.h> 111 112 #include <bus/pci/pcireg.h> 113 #include <bus/pci/pcivar.h> 114 115 #include "miibus_if.h" 116 117 #include <dev/netif/bce/if_bcereg.h> 118 #include <dev/netif/bce/if_bcefw.h> 119 120 #define BCE_MSI_CKINTVL ((10 * hz) / 1000) /* 10ms */ 121 122 #ifdef BCE_RSS_DEBUG 123 #define BCE_RSS_DPRINTF(sc, lvl, fmt, ...) \ 124 do { \ 125 if (sc->rss_debug >= lvl) \ 126 if_printf(&sc->arpcom.ac_if, fmt, __VA_ARGS__); \ 127 } while (0) 128 #else /* !BCE_RSS_DEBUG */ 129 #define BCE_RSS_DPRINTF(sc, lvl, fmt, ...) ((void)0) 130 #endif /* BCE_RSS_DEBUG */ 131 132 /****************************************************************************/ 133 /* PCI Device ID Table */ 134 /* */ 135 /* Used by bce_probe() to identify the devices supported by this driver. */ 136 /****************************************************************************/ 137 #define BCE_DEVDESC_MAX 64 138 139 static struct bce_type bce_devs[] = { 140 /* BCM5706C Controllers and OEM boards. */ 141 { BRCM_VENDORID, BRCM_DEVICEID_BCM5706, HP_VENDORID, 0x3101, 142 "HP NC370T Multifunction Gigabit Server Adapter" }, 143 { BRCM_VENDORID, BRCM_DEVICEID_BCM5706, HP_VENDORID, 0x3106, 144 "HP NC370i Multifunction Gigabit Server Adapter" }, 145 { BRCM_VENDORID, BRCM_DEVICEID_BCM5706, HP_VENDORID, 0x3070, 146 "HP NC380T PCIe DP Multifunc Gig Server Adapter" }, 147 { BRCM_VENDORID, BRCM_DEVICEID_BCM5706, HP_VENDORID, 0x1709, 148 "HP NC371i Multifunction Gigabit Server Adapter" }, 149 { BRCM_VENDORID, BRCM_DEVICEID_BCM5706, PCI_ANY_ID, PCI_ANY_ID, 150 "Broadcom NetXtreme II BCM5706 1000Base-T" }, 151 152 /* BCM5706S controllers and OEM boards. */ 153 { BRCM_VENDORID, BRCM_DEVICEID_BCM5706S, HP_VENDORID, 0x3102, 154 "HP NC370F Multifunction Gigabit Server Adapter" }, 155 { BRCM_VENDORID, BRCM_DEVICEID_BCM5706S, PCI_ANY_ID, PCI_ANY_ID, 156 "Broadcom NetXtreme II BCM5706 1000Base-SX" }, 157 158 /* BCM5708C controllers and OEM boards. */ 159 { BRCM_VENDORID, BRCM_DEVICEID_BCM5708, HP_VENDORID, 0x7037, 160 "HP NC373T PCIe Multifunction Gig Server Adapter" }, 161 { BRCM_VENDORID, BRCM_DEVICEID_BCM5708, HP_VENDORID, 0x7038, 162 "HP NC373i Multifunction Gigabit Server Adapter" }, 163 { BRCM_VENDORID, BRCM_DEVICEID_BCM5708, HP_VENDORID, 0x7045, 164 "HP NC374m PCIe Multifunction Adapter" }, 165 { BRCM_VENDORID, BRCM_DEVICEID_BCM5708, PCI_ANY_ID, PCI_ANY_ID, 166 "Broadcom NetXtreme II BCM5708 1000Base-T" }, 167 168 /* BCM5708S controllers and OEM boards. */ 169 { BRCM_VENDORID, BRCM_DEVICEID_BCM5708S, HP_VENDORID, 0x1706, 170 "HP NC373m Multifunction Gigabit Server Adapter" }, 171 { BRCM_VENDORID, BRCM_DEVICEID_BCM5708S, HP_VENDORID, 0x703b, 172 "HP NC373i Multifunction Gigabit Server Adapter" }, 173 { BRCM_VENDORID, BRCM_DEVICEID_BCM5708S, HP_VENDORID, 0x703d, 174 "HP NC373F PCIe Multifunc Giga Server Adapter" }, 175 { BRCM_VENDORID, BRCM_DEVICEID_BCM5708S, PCI_ANY_ID, PCI_ANY_ID, 176 "Broadcom NetXtreme II BCM5708S 1000Base-T" }, 177 178 /* BCM5709C controllers and OEM boards. */ 179 { BRCM_VENDORID, BRCM_DEVICEID_BCM5709, HP_VENDORID, 0x7055, 180 "HP NC382i DP Multifunction Gigabit Server Adapter" }, 181 { BRCM_VENDORID, BRCM_DEVICEID_BCM5709, HP_VENDORID, 0x7059, 182 "HP NC382T PCIe DP Multifunction Gigabit Server Adapter" }, 183 { BRCM_VENDORID, BRCM_DEVICEID_BCM5709, PCI_ANY_ID, PCI_ANY_ID, 184 "Broadcom NetXtreme II BCM5709 1000Base-T" }, 185 186 /* BCM5709S controllers and OEM boards. */ 187 { BRCM_VENDORID, BRCM_DEVICEID_BCM5709S, HP_VENDORID, 0x171d, 188 "HP NC382m DP 1GbE Multifunction BL-c Adapter" }, 189 { BRCM_VENDORID, BRCM_DEVICEID_BCM5709S, HP_VENDORID, 0x7056, 190 "HP NC382i DP Multifunction Gigabit Server Adapter" }, 191 { BRCM_VENDORID, BRCM_DEVICEID_BCM5709S, PCI_ANY_ID, PCI_ANY_ID, 192 "Broadcom NetXtreme II BCM5709 1000Base-SX" }, 193 194 /* BCM5716 controllers and OEM boards. */ 195 { BRCM_VENDORID, BRCM_DEVICEID_BCM5716, PCI_ANY_ID, PCI_ANY_ID, 196 "Broadcom NetXtreme II BCM5716 1000Base-T" }, 197 198 { 0, 0, 0, 0, NULL } 199 }; 200 201 /****************************************************************************/ 202 /* Supported Flash NVRAM device data. */ 203 /****************************************************************************/ 204 static const struct flash_spec flash_table[] = 205 { 206 #define BUFFERED_FLAGS (BCE_NV_BUFFERED | BCE_NV_TRANSLATE) 207 #define NONBUFFERED_FLAGS (BCE_NV_WREN) 208 209 /* Slow EEPROM */ 210 {0x00000000, 0x40830380, 0x009f0081, 0xa184a053, 0xaf000400, 211 BUFFERED_FLAGS, SEEPROM_PAGE_BITS, SEEPROM_PAGE_SIZE, 212 SEEPROM_BYTE_ADDR_MASK, SEEPROM_TOTAL_SIZE, 213 "EEPROM - slow"}, 214 /* Expansion entry 0001 */ 215 {0x08000002, 0x4b808201, 0x00050081, 0x03840253, 0xaf020406, 216 NONBUFFERED_FLAGS, SAIFUN_FLASH_PAGE_BITS, SAIFUN_FLASH_PAGE_SIZE, 217 SAIFUN_FLASH_BYTE_ADDR_MASK, 0, 218 "Entry 0001"}, 219 /* Saifun SA25F010 (non-buffered flash) */ 220 /* strap, cfg1, & write1 need updates */ 221 {0x04000001, 0x47808201, 0x00050081, 0x03840253, 0xaf020406, 222 NONBUFFERED_FLAGS, SAIFUN_FLASH_PAGE_BITS, SAIFUN_FLASH_PAGE_SIZE, 223 SAIFUN_FLASH_BYTE_ADDR_MASK, SAIFUN_FLASH_BASE_TOTAL_SIZE*2, 224 "Non-buffered flash (128kB)"}, 225 /* Saifun SA25F020 (non-buffered flash) */ 226 /* strap, cfg1, & write1 need updates */ 227 {0x0c000003, 0x4f808201, 0x00050081, 0x03840253, 0xaf020406, 228 NONBUFFERED_FLAGS, SAIFUN_FLASH_PAGE_BITS, SAIFUN_FLASH_PAGE_SIZE, 229 SAIFUN_FLASH_BYTE_ADDR_MASK, SAIFUN_FLASH_BASE_TOTAL_SIZE*4, 230 "Non-buffered flash (256kB)"}, 231 /* Expansion entry 0100 */ 232 {0x11000000, 0x53808201, 0x00050081, 0x03840253, 0xaf020406, 233 NONBUFFERED_FLAGS, SAIFUN_FLASH_PAGE_BITS, SAIFUN_FLASH_PAGE_SIZE, 234 SAIFUN_FLASH_BYTE_ADDR_MASK, 0, 235 "Entry 0100"}, 236 /* Entry 0101: ST M45PE10 (non-buffered flash, TetonII B0) */ 237 {0x19000002, 0x5b808201, 0x000500db, 0x03840253, 0xaf020406, 238 NONBUFFERED_FLAGS, ST_MICRO_FLASH_PAGE_BITS, ST_MICRO_FLASH_PAGE_SIZE, 239 ST_MICRO_FLASH_BYTE_ADDR_MASK, ST_MICRO_FLASH_BASE_TOTAL_SIZE*2, 240 "Entry 0101: ST M45PE10 (128kB non-bufferred)"}, 241 /* Entry 0110: ST M45PE20 (non-buffered flash)*/ 242 {0x15000001, 0x57808201, 0x000500db, 0x03840253, 0xaf020406, 243 NONBUFFERED_FLAGS, ST_MICRO_FLASH_PAGE_BITS, ST_MICRO_FLASH_PAGE_SIZE, 244 ST_MICRO_FLASH_BYTE_ADDR_MASK, ST_MICRO_FLASH_BASE_TOTAL_SIZE*4, 245 "Entry 0110: ST M45PE20 (256kB non-bufferred)"}, 246 /* Saifun SA25F005 (non-buffered flash) */ 247 /* strap, cfg1, & write1 need updates */ 248 {0x1d000003, 0x5f808201, 0x00050081, 0x03840253, 0xaf020406, 249 NONBUFFERED_FLAGS, SAIFUN_FLASH_PAGE_BITS, SAIFUN_FLASH_PAGE_SIZE, 250 SAIFUN_FLASH_BYTE_ADDR_MASK, SAIFUN_FLASH_BASE_TOTAL_SIZE, 251 "Non-buffered flash (64kB)"}, 252 /* Fast EEPROM */ 253 {0x22000000, 0x62808380, 0x009f0081, 0xa184a053, 0xaf000400, 254 BUFFERED_FLAGS, SEEPROM_PAGE_BITS, SEEPROM_PAGE_SIZE, 255 SEEPROM_BYTE_ADDR_MASK, SEEPROM_TOTAL_SIZE, 256 "EEPROM - fast"}, 257 /* Expansion entry 1001 */ 258 {0x2a000002, 0x6b808201, 0x00050081, 0x03840253, 0xaf020406, 259 NONBUFFERED_FLAGS, SAIFUN_FLASH_PAGE_BITS, SAIFUN_FLASH_PAGE_SIZE, 260 SAIFUN_FLASH_BYTE_ADDR_MASK, 0, 261 "Entry 1001"}, 262 /* Expansion entry 1010 */ 263 {0x26000001, 0x67808201, 0x00050081, 0x03840253, 0xaf020406, 264 NONBUFFERED_FLAGS, SAIFUN_FLASH_PAGE_BITS, SAIFUN_FLASH_PAGE_SIZE, 265 SAIFUN_FLASH_BYTE_ADDR_MASK, 0, 266 "Entry 1010"}, 267 /* ATMEL AT45DB011B (buffered flash) */ 268 {0x2e000003, 0x6e808273, 0x00570081, 0x68848353, 0xaf000400, 269 BUFFERED_FLAGS, BUFFERED_FLASH_PAGE_BITS, BUFFERED_FLASH_PAGE_SIZE, 270 BUFFERED_FLASH_BYTE_ADDR_MASK, BUFFERED_FLASH_TOTAL_SIZE, 271 "Buffered flash (128kB)"}, 272 /* Expansion entry 1100 */ 273 {0x33000000, 0x73808201, 0x00050081, 0x03840253, 0xaf020406, 274 NONBUFFERED_FLAGS, SAIFUN_FLASH_PAGE_BITS, SAIFUN_FLASH_PAGE_SIZE, 275 SAIFUN_FLASH_BYTE_ADDR_MASK, 0, 276 "Entry 1100"}, 277 /* Expansion entry 1101 */ 278 {0x3b000002, 0x7b808201, 0x00050081, 0x03840253, 0xaf020406, 279 NONBUFFERED_FLAGS, SAIFUN_FLASH_PAGE_BITS, SAIFUN_FLASH_PAGE_SIZE, 280 SAIFUN_FLASH_BYTE_ADDR_MASK, 0, 281 "Entry 1101"}, 282 /* Ateml Expansion entry 1110 */ 283 {0x37000001, 0x76808273, 0x00570081, 0x68848353, 0xaf000400, 284 BUFFERED_FLAGS, BUFFERED_FLASH_PAGE_BITS, BUFFERED_FLASH_PAGE_SIZE, 285 BUFFERED_FLASH_BYTE_ADDR_MASK, 0, 286 "Entry 1110 (Atmel)"}, 287 /* ATMEL AT45DB021B (buffered flash) */ 288 {0x3f000003, 0x7e808273, 0x00570081, 0x68848353, 0xaf000400, 289 BUFFERED_FLAGS, BUFFERED_FLASH_PAGE_BITS, BUFFERED_FLASH_PAGE_SIZE, 290 BUFFERED_FLASH_BYTE_ADDR_MASK, BUFFERED_FLASH_TOTAL_SIZE*2, 291 "Buffered flash (256kB)"}, 292 }; 293 294 /* 295 * The BCM5709 controllers transparently handle the 296 * differences between Atmel 264 byte pages and all 297 * flash devices which use 256 byte pages, so no 298 * logical-to-physical mapping is required in the 299 * driver. 300 */ 301 static struct flash_spec flash_5709 = { 302 .flags = BCE_NV_BUFFERED, 303 .page_bits = BCM5709_FLASH_PAGE_BITS, 304 .page_size = BCM5709_FLASH_PAGE_SIZE, 305 .addr_mask = BCM5709_FLASH_BYTE_ADDR_MASK, 306 .total_size = BUFFERED_FLASH_TOTAL_SIZE * 2, 307 .name = "5709/5716 buffered flash (256kB)", 308 }; 309 310 /****************************************************************************/ 311 /* DragonFly device entry points. */ 312 /****************************************************************************/ 313 static int bce_probe(device_t); 314 static int bce_attach(device_t); 315 static int bce_detach(device_t); 316 static void bce_shutdown(device_t); 317 static int bce_miibus_read_reg(device_t, int, int); 318 static int bce_miibus_write_reg(device_t, int, int, int); 319 static void bce_miibus_statchg(device_t); 320 321 /****************************************************************************/ 322 /* BCE Register/Memory Access Routines */ 323 /****************************************************************************/ 324 static uint32_t bce_reg_rd_ind(struct bce_softc *, uint32_t); 325 static void bce_reg_wr_ind(struct bce_softc *, uint32_t, uint32_t); 326 static void bce_shmem_wr(struct bce_softc *, uint32_t, uint32_t); 327 static uint32_t bce_shmem_rd(struct bce_softc *, u32); 328 static void bce_ctx_wr(struct bce_softc *, uint32_t, uint32_t, uint32_t); 329 330 /****************************************************************************/ 331 /* BCE NVRAM Access Routines */ 332 /****************************************************************************/ 333 static int bce_acquire_nvram_lock(struct bce_softc *); 334 static int bce_release_nvram_lock(struct bce_softc *); 335 static void bce_enable_nvram_access(struct bce_softc *); 336 static void bce_disable_nvram_access(struct bce_softc *); 337 static int bce_nvram_read_dword(struct bce_softc *, uint32_t, uint8_t *, 338 uint32_t); 339 static int bce_init_nvram(struct bce_softc *); 340 static int bce_nvram_read(struct bce_softc *, uint32_t, uint8_t *, int); 341 static int bce_nvram_test(struct bce_softc *); 342 343 /****************************************************************************/ 344 /* BCE DMA Allocate/Free Routines */ 345 /****************************************************************************/ 346 static int bce_dma_alloc(struct bce_softc *); 347 static void bce_dma_free(struct bce_softc *); 348 static void bce_dma_map_addr(void *, bus_dma_segment_t *, int, int); 349 350 /****************************************************************************/ 351 /* BCE Firmware Synchronization and Load */ 352 /****************************************************************************/ 353 static int bce_fw_sync(struct bce_softc *, uint32_t); 354 static void bce_load_rv2p_fw(struct bce_softc *, uint32_t *, 355 uint32_t, uint32_t); 356 static void bce_load_cpu_fw(struct bce_softc *, struct cpu_reg *, 357 struct fw_info *); 358 static void bce_start_cpu(struct bce_softc *, struct cpu_reg *); 359 static void bce_halt_cpu(struct bce_softc *, struct cpu_reg *); 360 static void bce_start_rxp_cpu(struct bce_softc *); 361 static void bce_init_rxp_cpu(struct bce_softc *); 362 static void bce_init_txp_cpu(struct bce_softc *); 363 static void bce_init_tpat_cpu(struct bce_softc *); 364 static void bce_init_cp_cpu(struct bce_softc *); 365 static void bce_init_com_cpu(struct bce_softc *); 366 static void bce_init_cpus(struct bce_softc *); 367 static void bce_setup_msix_table(struct bce_softc *); 368 static void bce_init_rss(struct bce_softc *); 369 370 static void bce_stop(struct bce_softc *); 371 static int bce_reset(struct bce_softc *, uint32_t); 372 static int bce_chipinit(struct bce_softc *); 373 static int bce_blockinit(struct bce_softc *); 374 static void bce_probe_pci_caps(struct bce_softc *); 375 static void bce_print_adapter_info(struct bce_softc *); 376 static void bce_get_media(struct bce_softc *); 377 static void bce_mgmt_init(struct bce_softc *); 378 static int bce_init_ctx(struct bce_softc *); 379 static void bce_get_mac_addr(struct bce_softc *); 380 static void bce_set_mac_addr(struct bce_softc *); 381 static void bce_set_rx_mode(struct bce_softc *); 382 static void bce_coal_change(struct bce_softc *); 383 static void bce_npoll_coal_change(struct bce_softc *); 384 static void bce_setup_serialize(struct bce_softc *); 385 static void bce_serialize_skipmain(struct bce_softc *); 386 static void bce_deserialize_skipmain(struct bce_softc *); 387 static void bce_set_timer_cpuid(struct bce_softc *, boolean_t); 388 static int bce_alloc_intr(struct bce_softc *); 389 static void bce_free_intr(struct bce_softc *); 390 static void bce_try_alloc_msix(struct bce_softc *); 391 static void bce_free_msix(struct bce_softc *, boolean_t); 392 static void bce_setup_ring_cnt(struct bce_softc *); 393 static int bce_setup_intr(struct bce_softc *); 394 static void bce_teardown_intr(struct bce_softc *); 395 static int bce_setup_msix(struct bce_softc *); 396 static void bce_teardown_msix(struct bce_softc *, int); 397 398 static int bce_create_tx_ring(struct bce_tx_ring *); 399 static void bce_destroy_tx_ring(struct bce_tx_ring *); 400 static void bce_init_tx_context(struct bce_tx_ring *); 401 static int bce_init_tx_chain(struct bce_tx_ring *); 402 static void bce_free_tx_chain(struct bce_tx_ring *); 403 static void bce_xmit(struct bce_tx_ring *); 404 static int bce_encap(struct bce_tx_ring *, struct mbuf **, int *); 405 static int bce_tso_setup(struct bce_tx_ring *, struct mbuf **, 406 uint16_t *, uint16_t *); 407 408 static int bce_create_rx_ring(struct bce_rx_ring *); 409 static void bce_destroy_rx_ring(struct bce_rx_ring *); 410 static void bce_init_rx_context(struct bce_rx_ring *); 411 static int bce_init_rx_chain(struct bce_rx_ring *); 412 static void bce_free_rx_chain(struct bce_rx_ring *); 413 static int bce_newbuf_std(struct bce_rx_ring *, uint16_t *, uint16_t, 414 uint32_t *, int); 415 static void bce_setup_rxdesc_std(struct bce_rx_ring *, uint16_t, 416 uint32_t *); 417 static struct pktinfo *bce_rss_pktinfo(struct pktinfo *, uint32_t, 418 const struct l2_fhdr *); 419 420 static void bce_start(struct ifnet *, struct ifaltq_subque *); 421 static int bce_ioctl(struct ifnet *, u_long, caddr_t, struct ucred *); 422 static void bce_watchdog(struct ifaltq_subque *); 423 static int bce_ifmedia_upd(struct ifnet *); 424 static void bce_ifmedia_sts(struct ifnet *, struct ifmediareq *); 425 static void bce_init(void *); 426 #ifdef IFPOLL_ENABLE 427 static void bce_npoll(struct ifnet *, struct ifpoll_info *); 428 static void bce_npoll_rx(struct ifnet *, void *, int); 429 static void bce_npoll_tx(struct ifnet *, void *, int); 430 static void bce_npoll_status(struct ifnet *); 431 static void bce_npoll_rx_pack(struct ifnet *, void *, int); 432 #endif 433 static void bce_serialize(struct ifnet *, enum ifnet_serialize); 434 static void bce_deserialize(struct ifnet *, enum ifnet_serialize); 435 static int bce_tryserialize(struct ifnet *, enum ifnet_serialize); 436 #ifdef INVARIANTS 437 static void bce_serialize_assert(struct ifnet *, enum ifnet_serialize, 438 boolean_t); 439 #endif 440 441 static void bce_intr(struct bce_softc *); 442 static void bce_intr_legacy(void *); 443 static void bce_intr_msi(void *); 444 static void bce_intr_msi_oneshot(void *); 445 static void bce_intr_msix_rxtx(void *); 446 static void bce_intr_msix_rx(void *); 447 static void bce_tx_intr(struct bce_tx_ring *, uint16_t); 448 static void bce_rx_intr(struct bce_rx_ring *, int, uint16_t); 449 static void bce_phy_intr(struct bce_softc *); 450 static void bce_disable_intr(struct bce_softc *); 451 static void bce_enable_intr(struct bce_softc *); 452 static void bce_reenable_intr(struct bce_rx_ring *); 453 static void bce_check_msi(void *); 454 455 static void bce_stats_update(struct bce_softc *); 456 static void bce_tick(void *); 457 static void bce_tick_serialized(struct bce_softc *); 458 static void bce_pulse(void *); 459 460 static void bce_add_sysctls(struct bce_softc *); 461 static int bce_sysctl_tx_bds_int(SYSCTL_HANDLER_ARGS); 462 static int bce_sysctl_tx_bds(SYSCTL_HANDLER_ARGS); 463 static int bce_sysctl_tx_ticks_int(SYSCTL_HANDLER_ARGS); 464 static int bce_sysctl_tx_ticks(SYSCTL_HANDLER_ARGS); 465 static int bce_sysctl_rx_bds_int(SYSCTL_HANDLER_ARGS); 466 static int bce_sysctl_rx_bds(SYSCTL_HANDLER_ARGS); 467 static int bce_sysctl_rx_ticks_int(SYSCTL_HANDLER_ARGS); 468 static int bce_sysctl_rx_ticks(SYSCTL_HANDLER_ARGS); 469 #ifdef IFPOLL_ENABLE 470 static int bce_sysctl_npoll_offset(SYSCTL_HANDLER_ARGS); 471 #endif 472 static int bce_sysctl_coal_change(SYSCTL_HANDLER_ARGS, 473 uint32_t *, uint32_t); 474 475 /* 476 * NOTE: 477 * Don't set bce_tx_ticks_int/bce_tx_ticks to 1023. Linux's bnx2 478 * takes 1023 as the TX ticks limit. However, using 1023 will 479 * cause 5708(B2) to generate extra interrupts (~2000/s) even when 480 * there is _no_ network activity on the NIC. 481 */ 482 static uint32_t bce_tx_bds_int = 255; /* bcm: 20 */ 483 static uint32_t bce_tx_bds = 255; /* bcm: 20 */ 484 static uint32_t bce_tx_ticks_int = 1022; /* bcm: 80 */ 485 static uint32_t bce_tx_ticks = 1022; /* bcm: 80 */ 486 static uint32_t bce_rx_bds_int = 128; /* bcm: 6 */ 487 static uint32_t bce_rx_bds = 0; /* bcm: 6 */ 488 static uint32_t bce_rx_ticks_int = 150; /* bcm: 18 */ 489 static uint32_t bce_rx_ticks = 150; /* bcm: 18 */ 490 491 static int bce_tx_wreg = 8; 492 493 static int bce_msi_enable = 1; 494 static int bce_msix_enable = 1; 495 496 static int bce_rx_pages = RX_PAGES_DEFAULT; 497 static int bce_tx_pages = TX_PAGES_DEFAULT; 498 499 static int bce_rx_rings = 0; /* auto */ 500 static int bce_tx_rings = 0; /* auto */ 501 502 TUNABLE_INT("hw.bce.tx_bds_int", &bce_tx_bds_int); 503 TUNABLE_INT("hw.bce.tx_bds", &bce_tx_bds); 504 TUNABLE_INT("hw.bce.tx_ticks_int", &bce_tx_ticks_int); 505 TUNABLE_INT("hw.bce.tx_ticks", &bce_tx_ticks); 506 TUNABLE_INT("hw.bce.rx_bds_int", &bce_rx_bds_int); 507 TUNABLE_INT("hw.bce.rx_bds", &bce_rx_bds); 508 TUNABLE_INT("hw.bce.rx_ticks_int", &bce_rx_ticks_int); 509 TUNABLE_INT("hw.bce.rx_ticks", &bce_rx_ticks); 510 TUNABLE_INT("hw.bce.msi.enable", &bce_msi_enable); 511 TUNABLE_INT("hw.bce.msix.enable", &bce_msix_enable); 512 TUNABLE_INT("hw.bce.rx_pages", &bce_rx_pages); 513 TUNABLE_INT("hw.bce.tx_pages", &bce_tx_pages); 514 TUNABLE_INT("hw.bce.tx_wreg", &bce_tx_wreg); 515 TUNABLE_INT("hw.bce.tx_rings", &bce_tx_rings); 516 TUNABLE_INT("hw.bce.rx_rings", &bce_rx_rings); 517 518 /****************************************************************************/ 519 /* DragonFly device dispatch table. */ 520 /****************************************************************************/ 521 static device_method_t bce_methods[] = { 522 /* Device interface */ 523 DEVMETHOD(device_probe, bce_probe), 524 DEVMETHOD(device_attach, bce_attach), 525 DEVMETHOD(device_detach, bce_detach), 526 DEVMETHOD(device_shutdown, bce_shutdown), 527 528 /* bus interface */ 529 DEVMETHOD(bus_print_child, bus_generic_print_child), 530 DEVMETHOD(bus_driver_added, bus_generic_driver_added), 531 532 /* MII interface */ 533 DEVMETHOD(miibus_readreg, bce_miibus_read_reg), 534 DEVMETHOD(miibus_writereg, bce_miibus_write_reg), 535 DEVMETHOD(miibus_statchg, bce_miibus_statchg), 536 537 DEVMETHOD_END 538 }; 539 540 static driver_t bce_driver = { 541 "bce", 542 bce_methods, 543 sizeof(struct bce_softc) 544 }; 545 546 static devclass_t bce_devclass; 547 548 DECLARE_DUMMY_MODULE(if_bce); 549 MODULE_DEPEND(bce, miibus, 1, 1, 1); 550 DRIVER_MODULE(if_bce, pci, bce_driver, bce_devclass, NULL, NULL); 551 DRIVER_MODULE(miibus, bce, miibus_driver, miibus_devclass, NULL, NULL); 552 553 /****************************************************************************/ 554 /* Device probe function. */ 555 /* */ 556 /* Compares the device to the driver's list of supported devices and */ 557 /* reports back to the OS whether this is the right driver for the device. */ 558 /* */ 559 /* Returns: */ 560 /* BUS_PROBE_DEFAULT on success, positive value on failure. */ 561 /****************************************************************************/ 562 static int 563 bce_probe(device_t dev) 564 { 565 struct bce_type *t; 566 uint16_t vid, did, svid, sdid; 567 568 /* Get the data for the device to be probed. */ 569 vid = pci_get_vendor(dev); 570 did = pci_get_device(dev); 571 svid = pci_get_subvendor(dev); 572 sdid = pci_get_subdevice(dev); 573 574 /* Look through the list of known devices for a match. */ 575 for (t = bce_devs; t->bce_name != NULL; ++t) { 576 if (vid == t->bce_vid && did == t->bce_did && 577 (svid == t->bce_svid || t->bce_svid == PCI_ANY_ID) && 578 (sdid == t->bce_sdid || t->bce_sdid == PCI_ANY_ID)) { 579 uint32_t revid = pci_read_config(dev, PCIR_REVID, 4); 580 char *descbuf; 581 582 descbuf = kmalloc(BCE_DEVDESC_MAX, M_TEMP, M_WAITOK); 583 584 /* Print out the device identity. */ 585 ksnprintf(descbuf, BCE_DEVDESC_MAX, "%s (%c%d)", 586 t->bce_name, 587 ((revid & 0xf0) >> 4) + 'A', revid & 0xf); 588 589 device_set_desc_copy(dev, descbuf); 590 kfree(descbuf, M_TEMP); 591 return 0; 592 } 593 } 594 return ENXIO; 595 } 596 597 /****************************************************************************/ 598 /* PCI Capabilities Probe Function. */ 599 /* */ 600 /* Walks the PCI capabiites list for the device to find what features are */ 601 /* supported. */ 602 /* */ 603 /* Returns: */ 604 /* None. */ 605 /****************************************************************************/ 606 static void 607 bce_print_adapter_info(struct bce_softc *sc) 608 { 609 device_printf(sc->bce_dev, "ASIC (0x%08X); ", sc->bce_chipid); 610 611 kprintf("Rev (%c%d); ", ((BCE_CHIP_ID(sc) & 0xf000) >> 12) + 'A', 612 ((BCE_CHIP_ID(sc) & 0x0ff0) >> 4)); 613 614 /* Bus info. */ 615 if (sc->bce_flags & BCE_PCIE_FLAG) { 616 kprintf("Bus (PCIe x%d, ", sc->link_width); 617 switch (sc->link_speed) { 618 case 1: 619 kprintf("2.5Gbps); "); 620 break; 621 case 2: 622 kprintf("5Gbps); "); 623 break; 624 default: 625 kprintf("Unknown link speed); "); 626 break; 627 } 628 } else { 629 kprintf("Bus (PCI%s, %s, %dMHz); ", 630 ((sc->bce_flags & BCE_PCIX_FLAG) ? "-X" : ""), 631 ((sc->bce_flags & BCE_PCI_32BIT_FLAG) ? "32-bit" : "64-bit"), 632 sc->bus_speed_mhz); 633 } 634 635 /* Firmware version and device features. */ 636 kprintf("B/C (%s)", sc->bce_bc_ver); 637 638 if ((sc->bce_flags & BCE_MFW_ENABLE_FLAG) || 639 (sc->bce_phy_flags & BCE_PHY_2_5G_CAPABLE_FLAG)) { 640 kprintf("; Flags("); 641 if (sc->bce_flags & BCE_MFW_ENABLE_FLAG) 642 kprintf("MFW[%s]", sc->bce_mfw_ver); 643 if (sc->bce_phy_flags & BCE_PHY_2_5G_CAPABLE_FLAG) 644 kprintf(" 2.5G"); 645 kprintf(")"); 646 } 647 kprintf("\n"); 648 } 649 650 /****************************************************************************/ 651 /* PCI Capabilities Probe Function. */ 652 /* */ 653 /* Walks the PCI capabiites list for the device to find what features are */ 654 /* supported. */ 655 /* */ 656 /* Returns: */ 657 /* None. */ 658 /****************************************************************************/ 659 static void 660 bce_probe_pci_caps(struct bce_softc *sc) 661 { 662 device_t dev = sc->bce_dev; 663 uint8_t ptr; 664 665 if (pci_is_pcix(dev)) 666 sc->bce_cap_flags |= BCE_PCIX_CAPABLE_FLAG; 667 668 ptr = pci_get_pciecap_ptr(dev); 669 if (ptr) { 670 uint16_t link_status = pci_read_config(dev, ptr + 0x12, 2); 671 672 sc->link_speed = link_status & 0xf; 673 sc->link_width = (link_status >> 4) & 0x3f; 674 sc->bce_cap_flags |= BCE_PCIE_CAPABLE_FLAG; 675 sc->bce_flags |= BCE_PCIE_FLAG; 676 } 677 } 678 679 /****************************************************************************/ 680 /* Device attach function. */ 681 /* */ 682 /* Allocates device resources, performs secondary chip identification, */ 683 /* resets and initializes the hardware, and initializes driver instance */ 684 /* variables. */ 685 /* */ 686 /* Returns: */ 687 /* 0 on success, positive value on failure. */ 688 /****************************************************************************/ 689 static int 690 bce_attach(device_t dev) 691 { 692 struct bce_softc *sc = device_get_softc(dev); 693 struct ifnet *ifp = &sc->arpcom.ac_if; 694 uint32_t val; 695 int rid, rc = 0; 696 int i, j; 697 struct mii_probe_args mii_args; 698 uintptr_t mii_priv = 0; 699 #ifdef IFPOLL_ENABLE 700 int offset, offset_def; 701 #endif 702 703 sc->bce_dev = dev; 704 if_initname(ifp, device_get_name(dev), device_get_unit(dev)); 705 706 lwkt_serialize_init(&sc->main_serialize); 707 for (i = 0; i < BCE_MSIX_MAX; ++i) { 708 struct bce_msix_data *msix = &sc->bce_msix[i]; 709 710 msix->msix_cpuid = -1; 711 msix->msix_rid = -1; 712 } 713 714 pci_enable_busmaster(dev); 715 716 bce_probe_pci_caps(sc); 717 718 /* Allocate PCI memory resources. */ 719 rid = PCIR_BAR(0); 720 sc->bce_res_mem = bus_alloc_resource_any(dev, SYS_RES_MEMORY, &rid, 721 RF_ACTIVE | PCI_RF_DENSE); 722 if (sc->bce_res_mem == NULL) { 723 device_printf(dev, "PCI memory allocation failed\n"); 724 return ENXIO; 725 } 726 sc->bce_btag = rman_get_bustag(sc->bce_res_mem); 727 sc->bce_bhandle = rman_get_bushandle(sc->bce_res_mem); 728 729 /* 730 * Configure byte swap and enable indirect register access. 731 * Rely on CPU to do target byte swapping on big endian systems. 732 * Access to registers outside of PCI configurtion space are not 733 * valid until this is done. 734 */ 735 pci_write_config(dev, BCE_PCICFG_MISC_CONFIG, 736 BCE_PCICFG_MISC_CONFIG_REG_WINDOW_ENA | 737 BCE_PCICFG_MISC_CONFIG_TARGET_MB_WORD_SWAP, 4); 738 739 /* Save ASIC revsion info. */ 740 sc->bce_chipid = REG_RD(sc, BCE_MISC_ID); 741 742 /* Weed out any non-production controller revisions. */ 743 switch (BCE_CHIP_ID(sc)) { 744 case BCE_CHIP_ID_5706_A0: 745 case BCE_CHIP_ID_5706_A1: 746 case BCE_CHIP_ID_5708_A0: 747 case BCE_CHIP_ID_5708_B0: 748 case BCE_CHIP_ID_5709_A0: 749 case BCE_CHIP_ID_5709_B0: 750 case BCE_CHIP_ID_5709_B1: 751 #ifdef foo 752 /* 5709C B2 seems to work fine */ 753 case BCE_CHIP_ID_5709_B2: 754 #endif 755 device_printf(dev, "Unsupported chip id 0x%08x!\n", 756 BCE_CHIP_ID(sc)); 757 rc = ENODEV; 758 goto fail; 759 } 760 761 mii_priv |= BRGPHY_FLAG_WIRESPEED; 762 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709) { 763 if (BCE_CHIP_REV(sc) == BCE_CHIP_REV_Ax || 764 BCE_CHIP_REV(sc) == BCE_CHIP_REV_Bx) 765 mii_priv |= BRGPHY_FLAG_NO_EARLYDAC; 766 } else { 767 mii_priv |= BRGPHY_FLAG_BER_BUG; 768 } 769 770 /* 771 * Find the base address for shared memory access. 772 * Newer versions of bootcode use a signature and offset 773 * while older versions use a fixed address. 774 */ 775 val = REG_RD_IND(sc, BCE_SHM_HDR_SIGNATURE); 776 if ((val & BCE_SHM_HDR_SIGNATURE_SIG_MASK) == 777 BCE_SHM_HDR_SIGNATURE_SIG) { 778 /* Multi-port devices use different offsets in shared memory. */ 779 sc->bce_shmem_base = REG_RD_IND(sc, 780 BCE_SHM_HDR_ADDR_0 + (pci_get_function(sc->bce_dev) << 2)); 781 } else { 782 sc->bce_shmem_base = HOST_VIEW_SHMEM_BASE; 783 } 784 785 /* Fetch the bootcode revision. */ 786 val = bce_shmem_rd(sc, BCE_DEV_INFO_BC_REV); 787 for (i = 0, j = 0; i < 3; i++) { 788 uint8_t num; 789 int k, skip0; 790 791 num = (uint8_t)(val >> (24 - (i * 8))); 792 for (k = 100, skip0 = 1; k >= 1; num %= k, k /= 10) { 793 if (num >= k || !skip0 || k == 1) { 794 sc->bce_bc_ver[j++] = (num / k) + '0'; 795 skip0 = 0; 796 } 797 } 798 if (i != 2) 799 sc->bce_bc_ver[j++] = '.'; 800 } 801 802 /* Check if any management firwmare is running. */ 803 val = bce_shmem_rd(sc, BCE_PORT_FEATURE); 804 if (val & BCE_PORT_FEATURE_ASF_ENABLED) { 805 sc->bce_flags |= BCE_MFW_ENABLE_FLAG; 806 807 /* Allow time for firmware to enter the running state. */ 808 for (i = 0; i < 30; i++) { 809 val = bce_shmem_rd(sc, BCE_BC_STATE_CONDITION); 810 if (val & BCE_CONDITION_MFW_RUN_MASK) 811 break; 812 DELAY(10000); 813 } 814 } 815 816 /* Check the current bootcode state. */ 817 val = bce_shmem_rd(sc, BCE_BC_STATE_CONDITION) & 818 BCE_CONDITION_MFW_RUN_MASK; 819 if (val != BCE_CONDITION_MFW_RUN_UNKNOWN && 820 val != BCE_CONDITION_MFW_RUN_NONE) { 821 uint32_t addr = bce_shmem_rd(sc, BCE_MFW_VER_PTR); 822 823 for (i = 0, j = 0; j < 3; j++) { 824 val = bce_reg_rd_ind(sc, addr + j * 4); 825 val = bswap32(val); 826 memcpy(&sc->bce_mfw_ver[i], &val, 4); 827 i += 4; 828 } 829 } 830 831 /* Get PCI bus information (speed and type). */ 832 val = REG_RD(sc, BCE_PCICFG_MISC_STATUS); 833 if (val & BCE_PCICFG_MISC_STATUS_PCIX_DET) { 834 uint32_t clkreg; 835 836 sc->bce_flags |= BCE_PCIX_FLAG; 837 838 clkreg = REG_RD(sc, BCE_PCICFG_PCI_CLOCK_CONTROL_BITS) & 839 BCE_PCICFG_PCI_CLOCK_CONTROL_BITS_PCI_CLK_SPD_DET; 840 switch (clkreg) { 841 case BCE_PCICFG_PCI_CLOCK_CONTROL_BITS_PCI_CLK_SPD_DET_133MHZ: 842 sc->bus_speed_mhz = 133; 843 break; 844 845 case BCE_PCICFG_PCI_CLOCK_CONTROL_BITS_PCI_CLK_SPD_DET_95MHZ: 846 sc->bus_speed_mhz = 100; 847 break; 848 849 case BCE_PCICFG_PCI_CLOCK_CONTROL_BITS_PCI_CLK_SPD_DET_66MHZ: 850 case BCE_PCICFG_PCI_CLOCK_CONTROL_BITS_PCI_CLK_SPD_DET_80MHZ: 851 sc->bus_speed_mhz = 66; 852 break; 853 854 case BCE_PCICFG_PCI_CLOCK_CONTROL_BITS_PCI_CLK_SPD_DET_48MHZ: 855 case BCE_PCICFG_PCI_CLOCK_CONTROL_BITS_PCI_CLK_SPD_DET_55MHZ: 856 sc->bus_speed_mhz = 50; 857 break; 858 859 case BCE_PCICFG_PCI_CLOCK_CONTROL_BITS_PCI_CLK_SPD_DET_LOW: 860 case BCE_PCICFG_PCI_CLOCK_CONTROL_BITS_PCI_CLK_SPD_DET_32MHZ: 861 case BCE_PCICFG_PCI_CLOCK_CONTROL_BITS_PCI_CLK_SPD_DET_38MHZ: 862 sc->bus_speed_mhz = 33; 863 break; 864 } 865 } else { 866 if (val & BCE_PCICFG_MISC_STATUS_M66EN) 867 sc->bus_speed_mhz = 66; 868 else 869 sc->bus_speed_mhz = 33; 870 } 871 872 if (val & BCE_PCICFG_MISC_STATUS_32BIT_DET) 873 sc->bce_flags |= BCE_PCI_32BIT_FLAG; 874 875 /* Reset the controller. */ 876 rc = bce_reset(sc, BCE_DRV_MSG_CODE_RESET); 877 if (rc != 0) 878 goto fail; 879 880 /* Initialize the controller. */ 881 rc = bce_chipinit(sc); 882 if (rc != 0) { 883 device_printf(dev, "Controller initialization failed!\n"); 884 goto fail; 885 } 886 887 /* Perform NVRAM test. */ 888 rc = bce_nvram_test(sc); 889 if (rc != 0) { 890 device_printf(dev, "NVRAM test failed!\n"); 891 goto fail; 892 } 893 894 /* Fetch the permanent Ethernet MAC address. */ 895 bce_get_mac_addr(sc); 896 897 /* 898 * Trip points control how many BDs 899 * should be ready before generating an 900 * interrupt while ticks control how long 901 * a BD can sit in the chain before 902 * generating an interrupt. Set the default 903 * values for the RX and TX rings. 904 */ 905 906 #ifdef BCE_DRBUG 907 /* Force more frequent interrupts. */ 908 sc->bce_tx_quick_cons_trip_int = 1; 909 sc->bce_tx_quick_cons_trip = 1; 910 sc->bce_tx_ticks_int = 0; 911 sc->bce_tx_ticks = 0; 912 913 sc->bce_rx_quick_cons_trip_int = 1; 914 sc->bce_rx_quick_cons_trip = 1; 915 sc->bce_rx_ticks_int = 0; 916 sc->bce_rx_ticks = 0; 917 #else 918 sc->bce_tx_quick_cons_trip_int = bce_tx_bds_int; 919 sc->bce_tx_quick_cons_trip = bce_tx_bds; 920 sc->bce_tx_ticks_int = bce_tx_ticks_int; 921 sc->bce_tx_ticks = bce_tx_ticks; 922 923 sc->bce_rx_quick_cons_trip_int = bce_rx_bds_int; 924 sc->bce_rx_quick_cons_trip = bce_rx_bds; 925 sc->bce_rx_ticks_int = bce_rx_ticks_int; 926 sc->bce_rx_ticks = bce_rx_ticks; 927 #endif 928 929 /* Update statistics once every second. */ 930 sc->bce_stats_ticks = 1000000 & 0xffff00; 931 932 /* Find the media type for the adapter. */ 933 bce_get_media(sc); 934 935 /* Find out RX/TX ring count */ 936 bce_setup_ring_cnt(sc); 937 938 /* Allocate DMA memory resources. */ 939 rc = bce_dma_alloc(sc); 940 if (rc != 0) { 941 device_printf(dev, "DMA resource allocation failed!\n"); 942 goto fail; 943 } 944 945 #ifdef IFPOLL_ENABLE 946 /* 947 * NPOLLING RX/TX CPU offset 948 */ 949 if (sc->rx_ring_cnt2 == ncpus2) { 950 offset = 0; 951 } else { 952 offset_def = (sc->rx_ring_cnt2 * device_get_unit(dev)) % ncpus2; 953 offset = device_getenv_int(dev, "npoll.offset", offset_def); 954 if (offset >= ncpus2 || 955 offset % sc->rx_ring_cnt2 != 0) { 956 device_printf(dev, "invalid npoll.offset %d, use %d\n", 957 offset, offset_def); 958 offset = offset_def; 959 } 960 } 961 sc->npoll_ofs = offset; 962 #endif 963 964 /* Allocate PCI IRQ resources. */ 965 rc = bce_alloc_intr(sc); 966 if (rc != 0) 967 goto fail; 968 969 /* Setup serializer */ 970 bce_setup_serialize(sc); 971 972 /* Initialize the ifnet interface. */ 973 ifp->if_softc = sc; 974 ifp->if_flags = IFF_BROADCAST | IFF_SIMPLEX | IFF_MULTICAST; 975 ifp->if_ioctl = bce_ioctl; 976 ifp->if_start = bce_start; 977 ifp->if_init = bce_init; 978 ifp->if_serialize = bce_serialize; 979 ifp->if_deserialize = bce_deserialize; 980 ifp->if_tryserialize = bce_tryserialize; 981 #ifdef INVARIANTS 982 ifp->if_serialize_assert = bce_serialize_assert; 983 #endif 984 #ifdef IFPOLL_ENABLE 985 ifp->if_npoll = bce_npoll; 986 #endif 987 988 ifp->if_mtu = ETHERMTU; 989 ifp->if_hwassist = BCE_CSUM_FEATURES | CSUM_TSO; 990 ifp->if_capabilities = BCE_IF_CAPABILITIES; 991 if (sc->rx_ring_cnt > 1) 992 ifp->if_capabilities |= IFCAP_RSS; 993 ifp->if_capenable = ifp->if_capabilities; 994 995 if (sc->bce_phy_flags & BCE_PHY_2_5G_CAPABLE_FLAG) 996 ifp->if_baudrate = IF_Gbps(2.5); 997 else 998 ifp->if_baudrate = IF_Gbps(1); 999 1000 ifp->if_nmbclusters = sc->rx_ring_cnt * USABLE_RX_BD(&sc->rx_rings[0]); 1001 1002 ifq_set_maxlen(&ifp->if_snd, USABLE_TX_BD(&sc->tx_rings[0])); 1003 ifq_set_ready(&ifp->if_snd); 1004 ifq_set_subq_cnt(&ifp->if_snd, sc->tx_ring_cnt); 1005 1006 if (sc->tx_ring_cnt > 1) { 1007 ifp->if_mapsubq = ifq_mapsubq_mask; 1008 ifq_set_subq_mask(&ifp->if_snd, sc->tx_ring_cnt - 1); 1009 } 1010 1011 /* 1012 * Look for our PHY. 1013 */ 1014 mii_probe_args_init(&mii_args, bce_ifmedia_upd, bce_ifmedia_sts); 1015 mii_args.mii_probemask = 1 << sc->bce_phy_addr; 1016 mii_args.mii_privtag = MII_PRIVTAG_BRGPHY; 1017 mii_args.mii_priv = mii_priv; 1018 1019 rc = mii_probe(dev, &sc->bce_miibus, &mii_args); 1020 if (rc != 0) { 1021 device_printf(dev, "PHY probe failed!\n"); 1022 goto fail; 1023 } 1024 1025 /* Attach to the Ethernet interface list. */ 1026 ether_ifattach(ifp, sc->eaddr, NULL); 1027 1028 /* Setup TX rings and subqueues */ 1029 for (i = 0; i < sc->tx_ring_cnt; ++i) { 1030 struct ifaltq_subque *ifsq = ifq_get_subq(&ifp->if_snd, i); 1031 struct bce_tx_ring *txr = &sc->tx_rings[i]; 1032 1033 ifsq_set_cpuid(ifsq, sc->bce_msix[i].msix_cpuid); 1034 ifsq_set_priv(ifsq, txr); 1035 ifsq_set_hw_serialize(ifsq, &txr->tx_serialize); 1036 txr->ifsq = ifsq; 1037 1038 ifsq_watchdog_init(&txr->tx_watchdog, ifsq, bce_watchdog); 1039 } 1040 1041 callout_init_mp(&sc->bce_tick_callout); 1042 callout_init_mp(&sc->bce_pulse_callout); 1043 callout_init_mp(&sc->bce_ckmsi_callout); 1044 1045 rc = bce_setup_intr(sc); 1046 if (rc != 0) { 1047 device_printf(dev, "Failed to setup IRQ!\n"); 1048 ether_ifdetach(ifp); 1049 goto fail; 1050 } 1051 1052 /* Set timer CPUID */ 1053 bce_set_timer_cpuid(sc, FALSE); 1054 1055 /* Add the supported sysctls to the kernel. */ 1056 bce_add_sysctls(sc); 1057 1058 /* 1059 * The chip reset earlier notified the bootcode that 1060 * a driver is present. We now need to start our pulse 1061 * routine so that the bootcode is reminded that we're 1062 * still running. 1063 */ 1064 bce_pulse(sc); 1065 1066 /* Get the firmware running so IPMI still works */ 1067 bce_mgmt_init(sc); 1068 1069 if (bootverbose) 1070 bce_print_adapter_info(sc); 1071 1072 return 0; 1073 fail: 1074 bce_detach(dev); 1075 return(rc); 1076 } 1077 1078 /****************************************************************************/ 1079 /* Device detach function. */ 1080 /* */ 1081 /* Stops the controller, resets the controller, and releases resources. */ 1082 /* */ 1083 /* Returns: */ 1084 /* 0 on success, positive value on failure. */ 1085 /****************************************************************************/ 1086 static int 1087 bce_detach(device_t dev) 1088 { 1089 struct bce_softc *sc = device_get_softc(dev); 1090 1091 if (device_is_attached(dev)) { 1092 struct ifnet *ifp = &sc->arpcom.ac_if; 1093 uint32_t msg; 1094 1095 ifnet_serialize_all(ifp); 1096 1097 /* Stop and reset the controller. */ 1098 callout_stop(&sc->bce_pulse_callout); 1099 bce_stop(sc); 1100 if (sc->bce_flags & BCE_NO_WOL_FLAG) 1101 msg = BCE_DRV_MSG_CODE_UNLOAD_LNK_DN; 1102 else 1103 msg = BCE_DRV_MSG_CODE_UNLOAD; 1104 bce_reset(sc, msg); 1105 1106 bce_teardown_intr(sc); 1107 1108 ifnet_deserialize_all(ifp); 1109 1110 ether_ifdetach(ifp); 1111 } 1112 1113 /* If we have a child device on the MII bus remove it too. */ 1114 if (sc->bce_miibus) 1115 device_delete_child(dev, sc->bce_miibus); 1116 bus_generic_detach(dev); 1117 1118 bce_free_intr(sc); 1119 1120 if (sc->bce_res_mem != NULL) { 1121 bus_release_resource(dev, SYS_RES_MEMORY, PCIR_BAR(0), 1122 sc->bce_res_mem); 1123 } 1124 1125 bce_dma_free(sc); 1126 1127 if (sc->serializes != NULL) 1128 kfree(sc->serializes, M_DEVBUF); 1129 1130 return 0; 1131 } 1132 1133 /****************************************************************************/ 1134 /* Device shutdown function. */ 1135 /* */ 1136 /* Stops and resets the controller. */ 1137 /* */ 1138 /* Returns: */ 1139 /* Nothing */ 1140 /****************************************************************************/ 1141 static void 1142 bce_shutdown(device_t dev) 1143 { 1144 struct bce_softc *sc = device_get_softc(dev); 1145 struct ifnet *ifp = &sc->arpcom.ac_if; 1146 uint32_t msg; 1147 1148 ifnet_serialize_all(ifp); 1149 1150 bce_stop(sc); 1151 if (sc->bce_flags & BCE_NO_WOL_FLAG) 1152 msg = BCE_DRV_MSG_CODE_UNLOAD_LNK_DN; 1153 else 1154 msg = BCE_DRV_MSG_CODE_UNLOAD; 1155 bce_reset(sc, msg); 1156 1157 ifnet_deserialize_all(ifp); 1158 } 1159 1160 /****************************************************************************/ 1161 /* Indirect register read. */ 1162 /* */ 1163 /* Reads NetXtreme II registers using an index/data register pair in PCI */ 1164 /* configuration space. Using this mechanism avoids issues with posted */ 1165 /* reads but is much slower than memory-mapped I/O. */ 1166 /* */ 1167 /* Returns: */ 1168 /* The value of the register. */ 1169 /****************************************************************************/ 1170 static uint32_t 1171 bce_reg_rd_ind(struct bce_softc *sc, uint32_t offset) 1172 { 1173 device_t dev = sc->bce_dev; 1174 1175 pci_write_config(dev, BCE_PCICFG_REG_WINDOW_ADDRESS, offset, 4); 1176 return pci_read_config(dev, BCE_PCICFG_REG_WINDOW, 4); 1177 } 1178 1179 /****************************************************************************/ 1180 /* Indirect register write. */ 1181 /* */ 1182 /* Writes NetXtreme II registers using an index/data register pair in PCI */ 1183 /* configuration space. Using this mechanism avoids issues with posted */ 1184 /* writes but is muchh slower than memory-mapped I/O. */ 1185 /* */ 1186 /* Returns: */ 1187 /* Nothing. */ 1188 /****************************************************************************/ 1189 static void 1190 bce_reg_wr_ind(struct bce_softc *sc, uint32_t offset, uint32_t val) 1191 { 1192 device_t dev = sc->bce_dev; 1193 1194 pci_write_config(dev, BCE_PCICFG_REG_WINDOW_ADDRESS, offset, 4); 1195 pci_write_config(dev, BCE_PCICFG_REG_WINDOW, val, 4); 1196 } 1197 1198 /****************************************************************************/ 1199 /* Shared memory write. */ 1200 /* */ 1201 /* Writes NetXtreme II shared memory region. */ 1202 /* */ 1203 /* Returns: */ 1204 /* Nothing. */ 1205 /****************************************************************************/ 1206 static void 1207 bce_shmem_wr(struct bce_softc *sc, uint32_t offset, uint32_t val) 1208 { 1209 bce_reg_wr_ind(sc, sc->bce_shmem_base + offset, val); 1210 } 1211 1212 /****************************************************************************/ 1213 /* Shared memory read. */ 1214 /* */ 1215 /* Reads NetXtreme II shared memory region. */ 1216 /* */ 1217 /* Returns: */ 1218 /* The 32 bit value read. */ 1219 /****************************************************************************/ 1220 static u32 1221 bce_shmem_rd(struct bce_softc *sc, uint32_t offset) 1222 { 1223 return bce_reg_rd_ind(sc, sc->bce_shmem_base + offset); 1224 } 1225 1226 /****************************************************************************/ 1227 /* Context memory write. */ 1228 /* */ 1229 /* The NetXtreme II controller uses context memory to track connection */ 1230 /* information for L2 and higher network protocols. */ 1231 /* */ 1232 /* Returns: */ 1233 /* Nothing. */ 1234 /****************************************************************************/ 1235 static void 1236 bce_ctx_wr(struct bce_softc *sc, uint32_t cid_addr, uint32_t ctx_offset, 1237 uint32_t ctx_val) 1238 { 1239 uint32_t idx, offset = ctx_offset + cid_addr; 1240 uint32_t val, retry_cnt = 5; 1241 1242 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 1243 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 1244 REG_WR(sc, BCE_CTX_CTX_DATA, ctx_val); 1245 REG_WR(sc, BCE_CTX_CTX_CTRL, (offset | BCE_CTX_CTX_CTRL_WRITE_REQ)); 1246 1247 for (idx = 0; idx < retry_cnt; idx++) { 1248 val = REG_RD(sc, BCE_CTX_CTX_CTRL); 1249 if ((val & BCE_CTX_CTX_CTRL_WRITE_REQ) == 0) 1250 break; 1251 DELAY(5); 1252 } 1253 1254 if (val & BCE_CTX_CTX_CTRL_WRITE_REQ) { 1255 device_printf(sc->bce_dev, 1256 "Unable to write CTX memory: " 1257 "cid_addr = 0x%08X, offset = 0x%08X!\n", 1258 cid_addr, ctx_offset); 1259 } 1260 } else { 1261 REG_WR(sc, BCE_CTX_DATA_ADR, offset); 1262 REG_WR(sc, BCE_CTX_DATA, ctx_val); 1263 } 1264 } 1265 1266 /****************************************************************************/ 1267 /* PHY register read. */ 1268 /* */ 1269 /* Implements register reads on the MII bus. */ 1270 /* */ 1271 /* Returns: */ 1272 /* The value of the register. */ 1273 /****************************************************************************/ 1274 static int 1275 bce_miibus_read_reg(device_t dev, int phy, int reg) 1276 { 1277 struct bce_softc *sc = device_get_softc(dev); 1278 uint32_t val; 1279 int i; 1280 1281 /* Make sure we are accessing the correct PHY address. */ 1282 KASSERT(phy == sc->bce_phy_addr, 1283 ("invalid phyno %d, should be %d\n", phy, sc->bce_phy_addr)); 1284 1285 if (sc->bce_phy_flags & BCE_PHY_INT_MODE_AUTO_POLLING_FLAG) { 1286 val = REG_RD(sc, BCE_EMAC_MDIO_MODE); 1287 val &= ~BCE_EMAC_MDIO_MODE_AUTO_POLL; 1288 1289 REG_WR(sc, BCE_EMAC_MDIO_MODE, val); 1290 REG_RD(sc, BCE_EMAC_MDIO_MODE); 1291 1292 DELAY(40); 1293 } 1294 1295 val = BCE_MIPHY(phy) | BCE_MIREG(reg) | 1296 BCE_EMAC_MDIO_COMM_COMMAND_READ | BCE_EMAC_MDIO_COMM_DISEXT | 1297 BCE_EMAC_MDIO_COMM_START_BUSY; 1298 REG_WR(sc, BCE_EMAC_MDIO_COMM, val); 1299 1300 for (i = 0; i < BCE_PHY_TIMEOUT; i++) { 1301 DELAY(10); 1302 1303 val = REG_RD(sc, BCE_EMAC_MDIO_COMM); 1304 if (!(val & BCE_EMAC_MDIO_COMM_START_BUSY)) { 1305 DELAY(5); 1306 1307 val = REG_RD(sc, BCE_EMAC_MDIO_COMM); 1308 val &= BCE_EMAC_MDIO_COMM_DATA; 1309 break; 1310 } 1311 } 1312 1313 if (val & BCE_EMAC_MDIO_COMM_START_BUSY) { 1314 if_printf(&sc->arpcom.ac_if, 1315 "Error: PHY read timeout! phy = %d, reg = 0x%04X\n", 1316 phy, reg); 1317 val = 0x0; 1318 } else { 1319 val = REG_RD(sc, BCE_EMAC_MDIO_COMM); 1320 } 1321 1322 if (sc->bce_phy_flags & BCE_PHY_INT_MODE_AUTO_POLLING_FLAG) { 1323 val = REG_RD(sc, BCE_EMAC_MDIO_MODE); 1324 val |= BCE_EMAC_MDIO_MODE_AUTO_POLL; 1325 1326 REG_WR(sc, BCE_EMAC_MDIO_MODE, val); 1327 REG_RD(sc, BCE_EMAC_MDIO_MODE); 1328 1329 DELAY(40); 1330 } 1331 return (val & 0xffff); 1332 } 1333 1334 /****************************************************************************/ 1335 /* PHY register write. */ 1336 /* */ 1337 /* Implements register writes on the MII bus. */ 1338 /* */ 1339 /* Returns: */ 1340 /* The value of the register. */ 1341 /****************************************************************************/ 1342 static int 1343 bce_miibus_write_reg(device_t dev, int phy, int reg, int val) 1344 { 1345 struct bce_softc *sc = device_get_softc(dev); 1346 uint32_t val1; 1347 int i; 1348 1349 /* Make sure we are accessing the correct PHY address. */ 1350 KASSERT(phy == sc->bce_phy_addr, 1351 ("invalid phyno %d, should be %d\n", phy, sc->bce_phy_addr)); 1352 1353 if (sc->bce_phy_flags & BCE_PHY_INT_MODE_AUTO_POLLING_FLAG) { 1354 val1 = REG_RD(sc, BCE_EMAC_MDIO_MODE); 1355 val1 &= ~BCE_EMAC_MDIO_MODE_AUTO_POLL; 1356 1357 REG_WR(sc, BCE_EMAC_MDIO_MODE, val1); 1358 REG_RD(sc, BCE_EMAC_MDIO_MODE); 1359 1360 DELAY(40); 1361 } 1362 1363 val1 = BCE_MIPHY(phy) | BCE_MIREG(reg) | val | 1364 BCE_EMAC_MDIO_COMM_COMMAND_WRITE | 1365 BCE_EMAC_MDIO_COMM_START_BUSY | BCE_EMAC_MDIO_COMM_DISEXT; 1366 REG_WR(sc, BCE_EMAC_MDIO_COMM, val1); 1367 1368 for (i = 0; i < BCE_PHY_TIMEOUT; i++) { 1369 DELAY(10); 1370 1371 val1 = REG_RD(sc, BCE_EMAC_MDIO_COMM); 1372 if (!(val1 & BCE_EMAC_MDIO_COMM_START_BUSY)) { 1373 DELAY(5); 1374 break; 1375 } 1376 } 1377 1378 if (val1 & BCE_EMAC_MDIO_COMM_START_BUSY) 1379 if_printf(&sc->arpcom.ac_if, "PHY write timeout!\n"); 1380 1381 if (sc->bce_phy_flags & BCE_PHY_INT_MODE_AUTO_POLLING_FLAG) { 1382 val1 = REG_RD(sc, BCE_EMAC_MDIO_MODE); 1383 val1 |= BCE_EMAC_MDIO_MODE_AUTO_POLL; 1384 1385 REG_WR(sc, BCE_EMAC_MDIO_MODE, val1); 1386 REG_RD(sc, BCE_EMAC_MDIO_MODE); 1387 1388 DELAY(40); 1389 } 1390 return 0; 1391 } 1392 1393 /****************************************************************************/ 1394 /* MII bus status change. */ 1395 /* */ 1396 /* Called by the MII bus driver when the PHY establishes link to set the */ 1397 /* MAC interface registers. */ 1398 /* */ 1399 /* Returns: */ 1400 /* Nothing. */ 1401 /****************************************************************************/ 1402 static void 1403 bce_miibus_statchg(device_t dev) 1404 { 1405 struct bce_softc *sc = device_get_softc(dev); 1406 struct mii_data *mii = device_get_softc(sc->bce_miibus); 1407 1408 BCE_CLRBIT(sc, BCE_EMAC_MODE, BCE_EMAC_MODE_PORT); 1409 1410 /* 1411 * Set MII or GMII interface based on the speed negotiated 1412 * by the PHY. 1413 */ 1414 if (IFM_SUBTYPE(mii->mii_media_active) == IFM_1000_T || 1415 IFM_SUBTYPE(mii->mii_media_active) == IFM_1000_SX) { 1416 BCE_SETBIT(sc, BCE_EMAC_MODE, BCE_EMAC_MODE_PORT_GMII); 1417 } else { 1418 BCE_SETBIT(sc, BCE_EMAC_MODE, BCE_EMAC_MODE_PORT_MII); 1419 } 1420 1421 /* 1422 * Set half or full duplex based on the duplicity negotiated 1423 * by the PHY. 1424 */ 1425 if ((mii->mii_media_active & IFM_GMASK) == IFM_FDX) { 1426 BCE_CLRBIT(sc, BCE_EMAC_MODE, BCE_EMAC_MODE_HALF_DUPLEX); 1427 } else { 1428 BCE_SETBIT(sc, BCE_EMAC_MODE, BCE_EMAC_MODE_HALF_DUPLEX); 1429 } 1430 } 1431 1432 /****************************************************************************/ 1433 /* Acquire NVRAM lock. */ 1434 /* */ 1435 /* Before the NVRAM can be accessed the caller must acquire an NVRAM lock. */ 1436 /* Locks 0 and 2 are reserved, lock 1 is used by firmware and lock 2 is */ 1437 /* for use by the driver. */ 1438 /* */ 1439 /* Returns: */ 1440 /* 0 on success, positive value on failure. */ 1441 /****************************************************************************/ 1442 static int 1443 bce_acquire_nvram_lock(struct bce_softc *sc) 1444 { 1445 uint32_t val; 1446 int j; 1447 1448 /* Request access to the flash interface. */ 1449 REG_WR(sc, BCE_NVM_SW_ARB, BCE_NVM_SW_ARB_ARB_REQ_SET2); 1450 for (j = 0; j < NVRAM_TIMEOUT_COUNT; j++) { 1451 val = REG_RD(sc, BCE_NVM_SW_ARB); 1452 if (val & BCE_NVM_SW_ARB_ARB_ARB2) 1453 break; 1454 1455 DELAY(5); 1456 } 1457 1458 if (j >= NVRAM_TIMEOUT_COUNT) { 1459 return EBUSY; 1460 } 1461 return 0; 1462 } 1463 1464 /****************************************************************************/ 1465 /* Release NVRAM lock. */ 1466 /* */ 1467 /* When the caller is finished accessing NVRAM the lock must be released. */ 1468 /* Locks 0 and 2 are reserved, lock 1 is used by firmware and lock 2 is */ 1469 /* for use by the driver. */ 1470 /* */ 1471 /* Returns: */ 1472 /* 0 on success, positive value on failure. */ 1473 /****************************************************************************/ 1474 static int 1475 bce_release_nvram_lock(struct bce_softc *sc) 1476 { 1477 int j; 1478 uint32_t val; 1479 1480 /* 1481 * Relinquish nvram interface. 1482 */ 1483 REG_WR(sc, BCE_NVM_SW_ARB, BCE_NVM_SW_ARB_ARB_REQ_CLR2); 1484 1485 for (j = 0; j < NVRAM_TIMEOUT_COUNT; j++) { 1486 val = REG_RD(sc, BCE_NVM_SW_ARB); 1487 if (!(val & BCE_NVM_SW_ARB_ARB_ARB2)) 1488 break; 1489 1490 DELAY(5); 1491 } 1492 1493 if (j >= NVRAM_TIMEOUT_COUNT) { 1494 return EBUSY; 1495 } 1496 return 0; 1497 } 1498 1499 /****************************************************************************/ 1500 /* Enable NVRAM access. */ 1501 /* */ 1502 /* Before accessing NVRAM for read or write operations the caller must */ 1503 /* enabled NVRAM access. */ 1504 /* */ 1505 /* Returns: */ 1506 /* Nothing. */ 1507 /****************************************************************************/ 1508 static void 1509 bce_enable_nvram_access(struct bce_softc *sc) 1510 { 1511 uint32_t val; 1512 1513 val = REG_RD(sc, BCE_NVM_ACCESS_ENABLE); 1514 /* Enable both bits, even on read. */ 1515 REG_WR(sc, BCE_NVM_ACCESS_ENABLE, 1516 val | BCE_NVM_ACCESS_ENABLE_EN | BCE_NVM_ACCESS_ENABLE_WR_EN); 1517 } 1518 1519 /****************************************************************************/ 1520 /* Disable NVRAM access. */ 1521 /* */ 1522 /* When the caller is finished accessing NVRAM access must be disabled. */ 1523 /* */ 1524 /* Returns: */ 1525 /* Nothing. */ 1526 /****************************************************************************/ 1527 static void 1528 bce_disable_nvram_access(struct bce_softc *sc) 1529 { 1530 uint32_t val; 1531 1532 val = REG_RD(sc, BCE_NVM_ACCESS_ENABLE); 1533 1534 /* Disable both bits, even after read. */ 1535 REG_WR(sc, BCE_NVM_ACCESS_ENABLE, 1536 val & ~(BCE_NVM_ACCESS_ENABLE_EN | BCE_NVM_ACCESS_ENABLE_WR_EN)); 1537 } 1538 1539 /****************************************************************************/ 1540 /* Read a dword (32 bits) from NVRAM. */ 1541 /* */ 1542 /* Read a 32 bit word from NVRAM. The caller is assumed to have already */ 1543 /* obtained the NVRAM lock and enabled the controller for NVRAM access. */ 1544 /* */ 1545 /* Returns: */ 1546 /* 0 on success and the 32 bit value read, positive value on failure. */ 1547 /****************************************************************************/ 1548 static int 1549 bce_nvram_read_dword(struct bce_softc *sc, uint32_t offset, uint8_t *ret_val, 1550 uint32_t cmd_flags) 1551 { 1552 uint32_t cmd; 1553 int i, rc = 0; 1554 1555 /* Build the command word. */ 1556 cmd = BCE_NVM_COMMAND_DOIT | cmd_flags; 1557 1558 /* Calculate the offset for buffered flash. */ 1559 if (sc->bce_flash_info->flags & BCE_NV_TRANSLATE) { 1560 offset = ((offset / sc->bce_flash_info->page_size) << 1561 sc->bce_flash_info->page_bits) + 1562 (offset % sc->bce_flash_info->page_size); 1563 } 1564 1565 /* 1566 * Clear the DONE bit separately, set the address to read, 1567 * and issue the read. 1568 */ 1569 REG_WR(sc, BCE_NVM_COMMAND, BCE_NVM_COMMAND_DONE); 1570 REG_WR(sc, BCE_NVM_ADDR, offset & BCE_NVM_ADDR_NVM_ADDR_VALUE); 1571 REG_WR(sc, BCE_NVM_COMMAND, cmd); 1572 1573 /* Wait for completion. */ 1574 for (i = 0; i < NVRAM_TIMEOUT_COUNT; i++) { 1575 uint32_t val; 1576 1577 DELAY(5); 1578 1579 val = REG_RD(sc, BCE_NVM_COMMAND); 1580 if (val & BCE_NVM_COMMAND_DONE) { 1581 val = REG_RD(sc, BCE_NVM_READ); 1582 1583 val = be32toh(val); 1584 memcpy(ret_val, &val, 4); 1585 break; 1586 } 1587 } 1588 1589 /* Check for errors. */ 1590 if (i >= NVRAM_TIMEOUT_COUNT) { 1591 if_printf(&sc->arpcom.ac_if, 1592 "Timeout error reading NVRAM at offset 0x%08X!\n", 1593 offset); 1594 rc = EBUSY; 1595 } 1596 return rc; 1597 } 1598 1599 /****************************************************************************/ 1600 /* Initialize NVRAM access. */ 1601 /* */ 1602 /* Identify the NVRAM device in use and prepare the NVRAM interface to */ 1603 /* access that device. */ 1604 /* */ 1605 /* Returns: */ 1606 /* 0 on success, positive value on failure. */ 1607 /****************************************************************************/ 1608 static int 1609 bce_init_nvram(struct bce_softc *sc) 1610 { 1611 uint32_t val; 1612 int j, entry_count, rc = 0; 1613 const struct flash_spec *flash; 1614 1615 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 1616 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 1617 sc->bce_flash_info = &flash_5709; 1618 goto bce_init_nvram_get_flash_size; 1619 } 1620 1621 /* Determine the selected interface. */ 1622 val = REG_RD(sc, BCE_NVM_CFG1); 1623 1624 entry_count = sizeof(flash_table) / sizeof(struct flash_spec); 1625 1626 /* 1627 * Flash reconfiguration is required to support additional 1628 * NVRAM devices not directly supported in hardware. 1629 * Check if the flash interface was reconfigured 1630 * by the bootcode. 1631 */ 1632 1633 if (val & 0x40000000) { 1634 /* Flash interface reconfigured by bootcode. */ 1635 for (j = 0, flash = flash_table; j < entry_count; 1636 j++, flash++) { 1637 if ((val & FLASH_BACKUP_STRAP_MASK) == 1638 (flash->config1 & FLASH_BACKUP_STRAP_MASK)) { 1639 sc->bce_flash_info = flash; 1640 break; 1641 } 1642 } 1643 } else { 1644 /* Flash interface not yet reconfigured. */ 1645 uint32_t mask; 1646 1647 if (val & (1 << 23)) 1648 mask = FLASH_BACKUP_STRAP_MASK; 1649 else 1650 mask = FLASH_STRAP_MASK; 1651 1652 /* Look for the matching NVRAM device configuration data. */ 1653 for (j = 0, flash = flash_table; j < entry_count; 1654 j++, flash++) { 1655 /* Check if the device matches any of the known devices. */ 1656 if ((val & mask) == (flash->strapping & mask)) { 1657 /* Found a device match. */ 1658 sc->bce_flash_info = flash; 1659 1660 /* Request access to the flash interface. */ 1661 rc = bce_acquire_nvram_lock(sc); 1662 if (rc != 0) 1663 return rc; 1664 1665 /* Reconfigure the flash interface. */ 1666 bce_enable_nvram_access(sc); 1667 REG_WR(sc, BCE_NVM_CFG1, flash->config1); 1668 REG_WR(sc, BCE_NVM_CFG2, flash->config2); 1669 REG_WR(sc, BCE_NVM_CFG3, flash->config3); 1670 REG_WR(sc, BCE_NVM_WRITE1, flash->write1); 1671 bce_disable_nvram_access(sc); 1672 bce_release_nvram_lock(sc); 1673 break; 1674 } 1675 } 1676 } 1677 1678 /* Check if a matching device was found. */ 1679 if (j == entry_count) { 1680 sc->bce_flash_info = NULL; 1681 if_printf(&sc->arpcom.ac_if, "Unknown Flash NVRAM found!\n"); 1682 return ENODEV; 1683 } 1684 1685 bce_init_nvram_get_flash_size: 1686 /* Write the flash config data to the shared memory interface. */ 1687 val = bce_shmem_rd(sc, BCE_SHARED_HW_CFG_CONFIG2) & 1688 BCE_SHARED_HW_CFG2_NVM_SIZE_MASK; 1689 if (val) 1690 sc->bce_flash_size = val; 1691 else 1692 sc->bce_flash_size = sc->bce_flash_info->total_size; 1693 1694 return rc; 1695 } 1696 1697 /****************************************************************************/ 1698 /* Read an arbitrary range of data from NVRAM. */ 1699 /* */ 1700 /* Prepares the NVRAM interface for access and reads the requested data */ 1701 /* into the supplied buffer. */ 1702 /* */ 1703 /* Returns: */ 1704 /* 0 on success and the data read, positive value on failure. */ 1705 /****************************************************************************/ 1706 static int 1707 bce_nvram_read(struct bce_softc *sc, uint32_t offset, uint8_t *ret_buf, 1708 int buf_size) 1709 { 1710 uint32_t cmd_flags, offset32, len32, extra; 1711 int rc = 0; 1712 1713 if (buf_size == 0) 1714 return 0; 1715 1716 /* Request access to the flash interface. */ 1717 rc = bce_acquire_nvram_lock(sc); 1718 if (rc != 0) 1719 return rc; 1720 1721 /* Enable access to flash interface */ 1722 bce_enable_nvram_access(sc); 1723 1724 len32 = buf_size; 1725 offset32 = offset; 1726 extra = 0; 1727 1728 cmd_flags = 0; 1729 1730 /* XXX should we release nvram lock if read_dword() fails? */ 1731 if (offset32 & 3) { 1732 uint8_t buf[4]; 1733 uint32_t pre_len; 1734 1735 offset32 &= ~3; 1736 pre_len = 4 - (offset & 3); 1737 1738 if (pre_len >= len32) { 1739 pre_len = len32; 1740 cmd_flags = BCE_NVM_COMMAND_FIRST | BCE_NVM_COMMAND_LAST; 1741 } else { 1742 cmd_flags = BCE_NVM_COMMAND_FIRST; 1743 } 1744 1745 rc = bce_nvram_read_dword(sc, offset32, buf, cmd_flags); 1746 if (rc) 1747 return rc; 1748 1749 memcpy(ret_buf, buf + (offset & 3), pre_len); 1750 1751 offset32 += 4; 1752 ret_buf += pre_len; 1753 len32 -= pre_len; 1754 } 1755 1756 if (len32 & 3) { 1757 extra = 4 - (len32 & 3); 1758 len32 = (len32 + 4) & ~3; 1759 } 1760 1761 if (len32 == 4) { 1762 uint8_t buf[4]; 1763 1764 if (cmd_flags) 1765 cmd_flags = BCE_NVM_COMMAND_LAST; 1766 else 1767 cmd_flags = BCE_NVM_COMMAND_FIRST | 1768 BCE_NVM_COMMAND_LAST; 1769 1770 rc = bce_nvram_read_dword(sc, offset32, buf, cmd_flags); 1771 1772 memcpy(ret_buf, buf, 4 - extra); 1773 } else if (len32 > 0) { 1774 uint8_t buf[4]; 1775 1776 /* Read the first word. */ 1777 if (cmd_flags) 1778 cmd_flags = 0; 1779 else 1780 cmd_flags = BCE_NVM_COMMAND_FIRST; 1781 1782 rc = bce_nvram_read_dword(sc, offset32, ret_buf, cmd_flags); 1783 1784 /* Advance to the next dword. */ 1785 offset32 += 4; 1786 ret_buf += 4; 1787 len32 -= 4; 1788 1789 while (len32 > 4 && rc == 0) { 1790 rc = bce_nvram_read_dword(sc, offset32, ret_buf, 0); 1791 1792 /* Advance to the next dword. */ 1793 offset32 += 4; 1794 ret_buf += 4; 1795 len32 -= 4; 1796 } 1797 1798 if (rc) 1799 goto bce_nvram_read_locked_exit; 1800 1801 cmd_flags = BCE_NVM_COMMAND_LAST; 1802 rc = bce_nvram_read_dword(sc, offset32, buf, cmd_flags); 1803 1804 memcpy(ret_buf, buf, 4 - extra); 1805 } 1806 1807 bce_nvram_read_locked_exit: 1808 /* Disable access to flash interface and release the lock. */ 1809 bce_disable_nvram_access(sc); 1810 bce_release_nvram_lock(sc); 1811 1812 return rc; 1813 } 1814 1815 /****************************************************************************/ 1816 /* Verifies that NVRAM is accessible and contains valid data. */ 1817 /* */ 1818 /* Reads the configuration data from NVRAM and verifies that the CRC is */ 1819 /* correct. */ 1820 /* */ 1821 /* Returns: */ 1822 /* 0 on success, positive value on failure. */ 1823 /****************************************************************************/ 1824 static int 1825 bce_nvram_test(struct bce_softc *sc) 1826 { 1827 uint32_t buf[BCE_NVRAM_SIZE / 4]; 1828 uint32_t magic, csum; 1829 uint8_t *data = (uint8_t *)buf; 1830 int rc = 0; 1831 1832 /* 1833 * Check that the device NVRAM is valid by reading 1834 * the magic value at offset 0. 1835 */ 1836 rc = bce_nvram_read(sc, 0, data, 4); 1837 if (rc != 0) 1838 return rc; 1839 1840 magic = be32toh(buf[0]); 1841 if (magic != BCE_NVRAM_MAGIC) { 1842 if_printf(&sc->arpcom.ac_if, 1843 "Invalid NVRAM magic value! Expected: 0x%08X, " 1844 "Found: 0x%08X\n", BCE_NVRAM_MAGIC, magic); 1845 return ENODEV; 1846 } 1847 1848 /* 1849 * Verify that the device NVRAM includes valid 1850 * configuration data. 1851 */ 1852 rc = bce_nvram_read(sc, 0x100, data, BCE_NVRAM_SIZE); 1853 if (rc != 0) 1854 return rc; 1855 1856 csum = ether_crc32_le(data, 0x100); 1857 if (csum != BCE_CRC32_RESIDUAL) { 1858 if_printf(&sc->arpcom.ac_if, 1859 "Invalid Manufacturing Information NVRAM CRC! " 1860 "Expected: 0x%08X, Found: 0x%08X\n", 1861 BCE_CRC32_RESIDUAL, csum); 1862 return ENODEV; 1863 } 1864 1865 csum = ether_crc32_le(data + 0x100, 0x100); 1866 if (csum != BCE_CRC32_RESIDUAL) { 1867 if_printf(&sc->arpcom.ac_if, 1868 "Invalid Feature Configuration Information " 1869 "NVRAM CRC! Expected: 0x%08X, Found: 08%08X\n", 1870 BCE_CRC32_RESIDUAL, csum); 1871 rc = ENODEV; 1872 } 1873 return rc; 1874 } 1875 1876 /****************************************************************************/ 1877 /* Identifies the current media type of the controller and sets the PHY */ 1878 /* address. */ 1879 /* */ 1880 /* Returns: */ 1881 /* Nothing. */ 1882 /****************************************************************************/ 1883 static void 1884 bce_get_media(struct bce_softc *sc) 1885 { 1886 uint32_t val; 1887 1888 sc->bce_phy_addr = 1; 1889 1890 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 1891 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 1892 uint32_t val = REG_RD(sc, BCE_MISC_DUAL_MEDIA_CTRL); 1893 uint32_t bond_id = val & BCE_MISC_DUAL_MEDIA_CTRL_BOND_ID; 1894 uint32_t strap; 1895 1896 /* 1897 * The BCM5709S is software configurable 1898 * for Copper or SerDes operation. 1899 */ 1900 if (bond_id == BCE_MISC_DUAL_MEDIA_CTRL_BOND_ID_C) { 1901 return; 1902 } else if (bond_id == BCE_MISC_DUAL_MEDIA_CTRL_BOND_ID_S) { 1903 sc->bce_phy_flags |= BCE_PHY_SERDES_FLAG; 1904 return; 1905 } 1906 1907 if (val & BCE_MISC_DUAL_MEDIA_CTRL_STRAP_OVERRIDE) { 1908 strap = (val & BCE_MISC_DUAL_MEDIA_CTRL_PHY_CTRL) >> 21; 1909 } else { 1910 strap = 1911 (val & BCE_MISC_DUAL_MEDIA_CTRL_PHY_CTRL_STRAP) >> 8; 1912 } 1913 1914 if (pci_get_function(sc->bce_dev) == 0) { 1915 switch (strap) { 1916 case 0x4: 1917 case 0x5: 1918 case 0x6: 1919 sc->bce_phy_flags |= BCE_PHY_SERDES_FLAG; 1920 break; 1921 } 1922 } else { 1923 switch (strap) { 1924 case 0x1: 1925 case 0x2: 1926 case 0x4: 1927 sc->bce_phy_flags |= BCE_PHY_SERDES_FLAG; 1928 break; 1929 } 1930 } 1931 } else if (BCE_CHIP_BOND_ID(sc) & BCE_CHIP_BOND_ID_SERDES_BIT) { 1932 sc->bce_phy_flags |= BCE_PHY_SERDES_FLAG; 1933 } 1934 1935 if (sc->bce_phy_flags & BCE_PHY_SERDES_FLAG) { 1936 sc->bce_flags |= BCE_NO_WOL_FLAG; 1937 if (BCE_CHIP_NUM(sc) != BCE_CHIP_NUM_5706) { 1938 sc->bce_phy_addr = 2; 1939 val = bce_shmem_rd(sc, BCE_SHARED_HW_CFG_CONFIG); 1940 if (val & BCE_SHARED_HW_CFG_PHY_2_5G) 1941 sc->bce_phy_flags |= BCE_PHY_2_5G_CAPABLE_FLAG; 1942 } 1943 } else if ((BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5706) || 1944 (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5708)) { 1945 sc->bce_phy_flags |= BCE_PHY_CRC_FIX_FLAG; 1946 } 1947 } 1948 1949 static void 1950 bce_destroy_tx_ring(struct bce_tx_ring *txr) 1951 { 1952 int i; 1953 1954 /* Destroy the TX buffer descriptor DMA stuffs. */ 1955 if (txr->tx_bd_chain_tag != NULL) { 1956 for (i = 0; i < txr->tx_pages; i++) { 1957 if (txr->tx_bd_chain[i] != NULL) { 1958 bus_dmamap_unload(txr->tx_bd_chain_tag, 1959 txr->tx_bd_chain_map[i]); 1960 bus_dmamem_free(txr->tx_bd_chain_tag, 1961 txr->tx_bd_chain[i], 1962 txr->tx_bd_chain_map[i]); 1963 } 1964 } 1965 bus_dma_tag_destroy(txr->tx_bd_chain_tag); 1966 } 1967 1968 /* Destroy the TX mbuf DMA stuffs. */ 1969 if (txr->tx_mbuf_tag != NULL) { 1970 for (i = 0; i < TOTAL_TX_BD(txr); i++) { 1971 /* Must have been unloaded in bce_stop() */ 1972 KKASSERT(txr->tx_bufs[i].tx_mbuf_ptr == NULL); 1973 bus_dmamap_destroy(txr->tx_mbuf_tag, 1974 txr->tx_bufs[i].tx_mbuf_map); 1975 } 1976 bus_dma_tag_destroy(txr->tx_mbuf_tag); 1977 } 1978 1979 if (txr->tx_bd_chain_map != NULL) 1980 kfree(txr->tx_bd_chain_map, M_DEVBUF); 1981 if (txr->tx_bd_chain != NULL) 1982 kfree(txr->tx_bd_chain, M_DEVBUF); 1983 if (txr->tx_bd_chain_paddr != NULL) 1984 kfree(txr->tx_bd_chain_paddr, M_DEVBUF); 1985 1986 if (txr->tx_bufs != NULL) 1987 kfree(txr->tx_bufs, M_DEVBUF); 1988 } 1989 1990 static void 1991 bce_destroy_rx_ring(struct bce_rx_ring *rxr) 1992 { 1993 int i; 1994 1995 /* Destroy the RX buffer descriptor DMA stuffs. */ 1996 if (rxr->rx_bd_chain_tag != NULL) { 1997 for (i = 0; i < rxr->rx_pages; i++) { 1998 if (rxr->rx_bd_chain[i] != NULL) { 1999 bus_dmamap_unload(rxr->rx_bd_chain_tag, 2000 rxr->rx_bd_chain_map[i]); 2001 bus_dmamem_free(rxr->rx_bd_chain_tag, 2002 rxr->rx_bd_chain[i], 2003 rxr->rx_bd_chain_map[i]); 2004 } 2005 } 2006 bus_dma_tag_destroy(rxr->rx_bd_chain_tag); 2007 } 2008 2009 /* Destroy the RX mbuf DMA stuffs. */ 2010 if (rxr->rx_mbuf_tag != NULL) { 2011 for (i = 0; i < TOTAL_RX_BD(rxr); i++) { 2012 /* Must have been unloaded in bce_stop() */ 2013 KKASSERT(rxr->rx_bufs[i].rx_mbuf_ptr == NULL); 2014 bus_dmamap_destroy(rxr->rx_mbuf_tag, 2015 rxr->rx_bufs[i].rx_mbuf_map); 2016 } 2017 bus_dmamap_destroy(rxr->rx_mbuf_tag, rxr->rx_mbuf_tmpmap); 2018 bus_dma_tag_destroy(rxr->rx_mbuf_tag); 2019 } 2020 2021 if (rxr->rx_bd_chain_map != NULL) 2022 kfree(rxr->rx_bd_chain_map, M_DEVBUF); 2023 if (rxr->rx_bd_chain != NULL) 2024 kfree(rxr->rx_bd_chain, M_DEVBUF); 2025 if (rxr->rx_bd_chain_paddr != NULL) 2026 kfree(rxr->rx_bd_chain_paddr, M_DEVBUF); 2027 2028 if (rxr->rx_bufs != NULL) 2029 kfree(rxr->rx_bufs, M_DEVBUF); 2030 } 2031 2032 /****************************************************************************/ 2033 /* Free any DMA memory owned by the driver. */ 2034 /* */ 2035 /* Scans through each data structre that requires DMA memory and frees */ 2036 /* the memory if allocated. */ 2037 /* */ 2038 /* Returns: */ 2039 /* Nothing. */ 2040 /****************************************************************************/ 2041 static void 2042 bce_dma_free(struct bce_softc *sc) 2043 { 2044 int i; 2045 2046 /* Destroy the status block. */ 2047 if (sc->status_tag != NULL) { 2048 if (sc->status_block != NULL) { 2049 bus_dmamap_unload(sc->status_tag, sc->status_map); 2050 bus_dmamem_free(sc->status_tag, sc->status_block, 2051 sc->status_map); 2052 } 2053 bus_dma_tag_destroy(sc->status_tag); 2054 } 2055 2056 /* Destroy the statistics block. */ 2057 if (sc->stats_tag != NULL) { 2058 if (sc->stats_block != NULL) { 2059 bus_dmamap_unload(sc->stats_tag, sc->stats_map); 2060 bus_dmamem_free(sc->stats_tag, sc->stats_block, 2061 sc->stats_map); 2062 } 2063 bus_dma_tag_destroy(sc->stats_tag); 2064 } 2065 2066 /* Destroy the CTX DMA stuffs. */ 2067 if (sc->ctx_tag != NULL) { 2068 for (i = 0; i < sc->ctx_pages; i++) { 2069 if (sc->ctx_block[i] != NULL) { 2070 bus_dmamap_unload(sc->ctx_tag, sc->ctx_map[i]); 2071 bus_dmamem_free(sc->ctx_tag, sc->ctx_block[i], 2072 sc->ctx_map[i]); 2073 } 2074 } 2075 bus_dma_tag_destroy(sc->ctx_tag); 2076 } 2077 2078 /* Free TX rings */ 2079 if (sc->tx_rings != NULL) { 2080 for (i = 0; i < sc->tx_ring_cnt; ++i) 2081 bce_destroy_tx_ring(&sc->tx_rings[i]); 2082 kfree(sc->tx_rings, M_DEVBUF); 2083 } 2084 2085 /* Free RX rings */ 2086 if (sc->rx_rings != NULL) { 2087 for (i = 0; i < sc->rx_ring_cnt; ++i) 2088 bce_destroy_rx_ring(&sc->rx_rings[i]); 2089 kfree(sc->rx_rings, M_DEVBUF); 2090 } 2091 2092 /* Destroy the parent tag */ 2093 if (sc->parent_tag != NULL) 2094 bus_dma_tag_destroy(sc->parent_tag); 2095 } 2096 2097 /****************************************************************************/ 2098 /* Get DMA memory from the OS. */ 2099 /* */ 2100 /* Validates that the OS has provided DMA buffers in response to a */ 2101 /* bus_dmamap_load() call and saves the physical address of those buffers. */ 2102 /* When the callback is used the OS will return 0 for the mapping function */ 2103 /* (bus_dmamap_load()) so we use the value of map_arg->maxsegs to pass any */ 2104 /* failures back to the caller. */ 2105 /* */ 2106 /* Returns: */ 2107 /* Nothing. */ 2108 /****************************************************************************/ 2109 static void 2110 bce_dma_map_addr(void *arg, bus_dma_segment_t *segs, int nseg, int error) 2111 { 2112 bus_addr_t *busaddr = arg; 2113 2114 /* Check for an error and signal the caller that an error occurred. */ 2115 if (error) 2116 return; 2117 2118 KASSERT(nseg == 1, ("only one segment is allowed")); 2119 *busaddr = segs->ds_addr; 2120 } 2121 2122 static int 2123 bce_create_tx_ring(struct bce_tx_ring *txr) 2124 { 2125 int pages, rc, i; 2126 2127 lwkt_serialize_init(&txr->tx_serialize); 2128 txr->tx_wreg = bce_tx_wreg; 2129 2130 pages = device_getenv_int(txr->sc->bce_dev, "tx_pages", bce_tx_pages); 2131 if (pages <= 0 || pages > TX_PAGES_MAX || !powerof2(pages)) { 2132 device_printf(txr->sc->bce_dev, "invalid # of TX pages\n"); 2133 pages = TX_PAGES_DEFAULT; 2134 } 2135 txr->tx_pages = pages; 2136 2137 txr->tx_bd_chain_map = kmalloc(sizeof(bus_dmamap_t) * txr->tx_pages, 2138 M_DEVBUF, M_WAITOK | M_ZERO); 2139 txr->tx_bd_chain = kmalloc(sizeof(struct tx_bd *) * txr->tx_pages, 2140 M_DEVBUF, M_WAITOK | M_ZERO); 2141 txr->tx_bd_chain_paddr = kmalloc(sizeof(bus_addr_t) * txr->tx_pages, 2142 M_DEVBUF, M_WAITOK | M_ZERO); 2143 2144 txr->tx_bufs = kmalloc_cachealign( 2145 sizeof(struct bce_tx_buf) * TOTAL_TX_BD(txr), 2146 M_DEVBUF, M_WAITOK | M_ZERO); 2147 2148 /* 2149 * Create a DMA tag for the TX buffer descriptor chain, 2150 * allocate and clear the memory, and fetch the 2151 * physical address of the block. 2152 */ 2153 rc = bus_dma_tag_create(txr->sc->parent_tag, BCM_PAGE_SIZE, 0, 2154 BUS_SPACE_MAXADDR, BUS_SPACE_MAXADDR, NULL, NULL, 2155 BCE_TX_CHAIN_PAGE_SZ, 1, BCE_TX_CHAIN_PAGE_SZ, 2156 0, &txr->tx_bd_chain_tag); 2157 if (rc != 0) { 2158 device_printf(txr->sc->bce_dev, "Could not allocate " 2159 "TX descriptor chain DMA tag!\n"); 2160 return rc; 2161 } 2162 2163 for (i = 0; i < txr->tx_pages; i++) { 2164 bus_addr_t busaddr; 2165 2166 rc = bus_dmamem_alloc(txr->tx_bd_chain_tag, 2167 (void **)&txr->tx_bd_chain[i], 2168 BUS_DMA_WAITOK | BUS_DMA_ZERO | BUS_DMA_COHERENT, 2169 &txr->tx_bd_chain_map[i]); 2170 if (rc != 0) { 2171 device_printf(txr->sc->bce_dev, 2172 "Could not allocate %dth TX descriptor " 2173 "chain DMA memory!\n", i); 2174 return rc; 2175 } 2176 2177 rc = bus_dmamap_load(txr->tx_bd_chain_tag, 2178 txr->tx_bd_chain_map[i], 2179 txr->tx_bd_chain[i], 2180 BCE_TX_CHAIN_PAGE_SZ, 2181 bce_dma_map_addr, &busaddr, 2182 BUS_DMA_WAITOK); 2183 if (rc != 0) { 2184 if (rc == EINPROGRESS) { 2185 panic("%s coherent memory loading " 2186 "is still in progress!", 2187 txr->sc->arpcom.ac_if.if_xname); 2188 } 2189 device_printf(txr->sc->bce_dev, "Could not map %dth " 2190 "TX descriptor chain DMA memory!\n", i); 2191 bus_dmamem_free(txr->tx_bd_chain_tag, 2192 txr->tx_bd_chain[i], 2193 txr->tx_bd_chain_map[i]); 2194 txr->tx_bd_chain[i] = NULL; 2195 return rc; 2196 } 2197 2198 txr->tx_bd_chain_paddr[i] = busaddr; 2199 } 2200 2201 /* Create a DMA tag for TX mbufs. */ 2202 rc = bus_dma_tag_create(txr->sc->parent_tag, 1, 0, 2203 BUS_SPACE_MAXADDR, BUS_SPACE_MAXADDR, NULL, NULL, 2204 IP_MAXPACKET + sizeof(struct ether_vlan_header), 2205 BCE_MAX_SEGMENTS, PAGE_SIZE, 2206 BUS_DMA_ALLOCNOW | BUS_DMA_WAITOK | BUS_DMA_ONEBPAGE, 2207 &txr->tx_mbuf_tag); 2208 if (rc != 0) { 2209 device_printf(txr->sc->bce_dev, 2210 "Could not allocate TX mbuf DMA tag!\n"); 2211 return rc; 2212 } 2213 2214 /* Create DMA maps for the TX mbufs clusters. */ 2215 for (i = 0; i < TOTAL_TX_BD(txr); i++) { 2216 rc = bus_dmamap_create(txr->tx_mbuf_tag, 2217 BUS_DMA_WAITOK | BUS_DMA_ONEBPAGE, 2218 &txr->tx_bufs[i].tx_mbuf_map); 2219 if (rc != 0) { 2220 int j; 2221 2222 for (j = 0; j < i; ++j) { 2223 bus_dmamap_destroy(txr->tx_mbuf_tag, 2224 txr->tx_bufs[j].tx_mbuf_map); 2225 } 2226 bus_dma_tag_destroy(txr->tx_mbuf_tag); 2227 txr->tx_mbuf_tag = NULL; 2228 2229 device_printf(txr->sc->bce_dev, "Unable to create " 2230 "%dth TX mbuf DMA map!\n", i); 2231 return rc; 2232 } 2233 } 2234 return 0; 2235 } 2236 2237 static int 2238 bce_create_rx_ring(struct bce_rx_ring *rxr) 2239 { 2240 int pages, rc, i; 2241 2242 lwkt_serialize_init(&rxr->rx_serialize); 2243 2244 pages = device_getenv_int(rxr->sc->bce_dev, "rx_pages", bce_rx_pages); 2245 if (pages <= 0 || pages > RX_PAGES_MAX || !powerof2(pages)) { 2246 device_printf(rxr->sc->bce_dev, "invalid # of RX pages\n"); 2247 pages = RX_PAGES_DEFAULT; 2248 } 2249 rxr->rx_pages = pages; 2250 2251 rxr->rx_bd_chain_map = kmalloc(sizeof(bus_dmamap_t) * rxr->rx_pages, 2252 M_DEVBUF, M_WAITOK | M_ZERO); 2253 rxr->rx_bd_chain = kmalloc(sizeof(struct rx_bd *) * rxr->rx_pages, 2254 M_DEVBUF, M_WAITOK | M_ZERO); 2255 rxr->rx_bd_chain_paddr = kmalloc(sizeof(bus_addr_t) * rxr->rx_pages, 2256 M_DEVBUF, M_WAITOK | M_ZERO); 2257 2258 rxr->rx_bufs = kmalloc_cachealign( 2259 sizeof(struct bce_rx_buf) * TOTAL_RX_BD(rxr), 2260 M_DEVBUF, M_WAITOK | M_ZERO); 2261 2262 /* 2263 * Create a DMA tag for the RX buffer descriptor chain, 2264 * allocate and clear the memory, and fetch the physical 2265 * address of the blocks. 2266 */ 2267 rc = bus_dma_tag_create(rxr->sc->parent_tag, BCM_PAGE_SIZE, 0, 2268 BUS_SPACE_MAXADDR, BUS_SPACE_MAXADDR, NULL, NULL, 2269 BCE_RX_CHAIN_PAGE_SZ, 1, BCE_RX_CHAIN_PAGE_SZ, 2270 0, &rxr->rx_bd_chain_tag); 2271 if (rc != 0) { 2272 device_printf(rxr->sc->bce_dev, "Could not allocate " 2273 "RX descriptor chain DMA tag!\n"); 2274 return rc; 2275 } 2276 2277 for (i = 0; i < rxr->rx_pages; i++) { 2278 bus_addr_t busaddr; 2279 2280 rc = bus_dmamem_alloc(rxr->rx_bd_chain_tag, 2281 (void **)&rxr->rx_bd_chain[i], 2282 BUS_DMA_WAITOK | BUS_DMA_ZERO | BUS_DMA_COHERENT, 2283 &rxr->rx_bd_chain_map[i]); 2284 if (rc != 0) { 2285 device_printf(rxr->sc->bce_dev, 2286 "Could not allocate %dth RX descriptor " 2287 "chain DMA memory!\n", i); 2288 return rc; 2289 } 2290 2291 rc = bus_dmamap_load(rxr->rx_bd_chain_tag, 2292 rxr->rx_bd_chain_map[i], 2293 rxr->rx_bd_chain[i], 2294 BCE_RX_CHAIN_PAGE_SZ, 2295 bce_dma_map_addr, &busaddr, 2296 BUS_DMA_WAITOK); 2297 if (rc != 0) { 2298 if (rc == EINPROGRESS) { 2299 panic("%s coherent memory loading " 2300 "is still in progress!", 2301 rxr->sc->arpcom.ac_if.if_xname); 2302 } 2303 device_printf(rxr->sc->bce_dev, 2304 "Could not map %dth RX descriptor " 2305 "chain DMA memory!\n", i); 2306 bus_dmamem_free(rxr->rx_bd_chain_tag, 2307 rxr->rx_bd_chain[i], 2308 rxr->rx_bd_chain_map[i]); 2309 rxr->rx_bd_chain[i] = NULL; 2310 return rc; 2311 } 2312 2313 rxr->rx_bd_chain_paddr[i] = busaddr; 2314 } 2315 2316 /* Create a DMA tag for RX mbufs. */ 2317 rc = bus_dma_tag_create(rxr->sc->parent_tag, BCE_DMA_RX_ALIGN, 0, 2318 BUS_SPACE_MAXADDR, BUS_SPACE_MAXADDR, NULL, NULL, 2319 MCLBYTES, 1, MCLBYTES, 2320 BUS_DMA_ALLOCNOW | BUS_DMA_ALIGNED | BUS_DMA_WAITOK, 2321 &rxr->rx_mbuf_tag); 2322 if (rc != 0) { 2323 device_printf(rxr->sc->bce_dev, 2324 "Could not allocate RX mbuf DMA tag!\n"); 2325 return rc; 2326 } 2327 2328 /* Create tmp DMA map for RX mbuf clusters. */ 2329 rc = bus_dmamap_create(rxr->rx_mbuf_tag, BUS_DMA_WAITOK, 2330 &rxr->rx_mbuf_tmpmap); 2331 if (rc != 0) { 2332 bus_dma_tag_destroy(rxr->rx_mbuf_tag); 2333 rxr->rx_mbuf_tag = NULL; 2334 2335 device_printf(rxr->sc->bce_dev, 2336 "Could not create RX mbuf tmp DMA map!\n"); 2337 return rc; 2338 } 2339 2340 /* Create DMA maps for the RX mbuf clusters. */ 2341 for (i = 0; i < TOTAL_RX_BD(rxr); i++) { 2342 rc = bus_dmamap_create(rxr->rx_mbuf_tag, BUS_DMA_WAITOK, 2343 &rxr->rx_bufs[i].rx_mbuf_map); 2344 if (rc != 0) { 2345 int j; 2346 2347 for (j = 0; j < i; ++j) { 2348 bus_dmamap_destroy(rxr->rx_mbuf_tag, 2349 rxr->rx_bufs[j].rx_mbuf_map); 2350 } 2351 bus_dma_tag_destroy(rxr->rx_mbuf_tag); 2352 rxr->rx_mbuf_tag = NULL; 2353 2354 device_printf(rxr->sc->bce_dev, "Unable to create " 2355 "%dth RX mbuf DMA map!\n", i); 2356 return rc; 2357 } 2358 } 2359 return 0; 2360 } 2361 2362 /****************************************************************************/ 2363 /* Allocate any DMA memory needed by the driver. */ 2364 /* */ 2365 /* Allocates DMA memory needed for the various global structures needed by */ 2366 /* hardware. */ 2367 /* */ 2368 /* Memory alignment requirements: */ 2369 /* -----------------+----------+----------+----------+----------+ */ 2370 /* Data Structure | 5706 | 5708 | 5709 | 5716 | */ 2371 /* -----------------+----------+----------+----------+----------+ */ 2372 /* Status Block | 8 bytes | 8 bytes | 16 bytes | 16 bytes | */ 2373 /* Statistics Block | 8 bytes | 8 bytes | 16 bytes | 16 bytes | */ 2374 /* RX Buffers | 16 bytes | 16 bytes | 16 bytes | 16 bytes | */ 2375 /* PG Buffers | none | none | none | none | */ 2376 /* TX Buffers | none | none | none | none | */ 2377 /* Chain Pages(1) | 4KiB | 4KiB | 4KiB | 4KiB | */ 2378 /* Context Pages(1) | N/A | N/A | 4KiB | 4KiB | */ 2379 /* -----------------+----------+----------+----------+----------+ */ 2380 /* */ 2381 /* (1) Must align with CPU page size (BCM_PAGE_SZIE). */ 2382 /* */ 2383 /* Returns: */ 2384 /* 0 for success, positive value for failure. */ 2385 /****************************************************************************/ 2386 static int 2387 bce_dma_alloc(struct bce_softc *sc) 2388 { 2389 struct ifnet *ifp = &sc->arpcom.ac_if; 2390 int i, rc = 0; 2391 bus_addr_t busaddr, max_busaddr; 2392 bus_size_t status_align, stats_align, status_size; 2393 2394 /* 2395 * The embedded PCIe to PCI-X bridge (EPB) 2396 * in the 5708 cannot address memory above 2397 * 40 bits (E7_5708CB1_23043 & E6_5708SB1_23043). 2398 */ 2399 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5708) 2400 max_busaddr = BCE_BUS_SPACE_MAXADDR; 2401 else 2402 max_busaddr = BUS_SPACE_MAXADDR; 2403 2404 /* 2405 * BCM5709 and BCM5716 uses host memory as cache for context memory. 2406 */ 2407 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 2408 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 2409 sc->ctx_pages = BCE_CTX_BLK_SZ / BCM_PAGE_SIZE; 2410 if (sc->ctx_pages == 0) 2411 sc->ctx_pages = 1; 2412 if (sc->ctx_pages > BCE_CTX_PAGES) { 2413 device_printf(sc->bce_dev, "excessive ctx pages %d\n", 2414 sc->ctx_pages); 2415 return ENOMEM; 2416 } 2417 status_align = 16; 2418 stats_align = 16; 2419 } else { 2420 status_align = 8; 2421 stats_align = 8; 2422 } 2423 2424 /* 2425 * Each MSI-X vector needs a status block; each status block 2426 * consumes 128bytes and is 128bytes aligned. 2427 */ 2428 if (sc->rx_ring_cnt > 1) { 2429 status_size = BCE_MSIX_MAX * BCE_STATUS_BLK_MSIX_ALIGN; 2430 status_align = BCE_STATUS_BLK_MSIX_ALIGN; 2431 } else { 2432 status_size = BCE_STATUS_BLK_SZ; 2433 } 2434 2435 /* 2436 * Allocate the parent bus DMA tag appropriate for PCI. 2437 */ 2438 rc = bus_dma_tag_create(NULL, 1, BCE_DMA_BOUNDARY, 2439 max_busaddr, BUS_SPACE_MAXADDR, 2440 NULL, NULL, 2441 BUS_SPACE_MAXSIZE_32BIT, 0, 2442 BUS_SPACE_MAXSIZE_32BIT, 2443 0, &sc->parent_tag); 2444 if (rc != 0) { 2445 if_printf(ifp, "Could not allocate parent DMA tag!\n"); 2446 return rc; 2447 } 2448 2449 /* 2450 * Allocate status block. 2451 */ 2452 sc->status_block = bus_dmamem_coherent_any(sc->parent_tag, 2453 status_align, status_size, 2454 BUS_DMA_WAITOK | BUS_DMA_ZERO, 2455 &sc->status_tag, &sc->status_map, 2456 &sc->status_block_paddr); 2457 if (sc->status_block == NULL) { 2458 if_printf(ifp, "Could not allocate status block!\n"); 2459 return ENOMEM; 2460 } 2461 2462 /* 2463 * Allocate statistics block. 2464 */ 2465 sc->stats_block = bus_dmamem_coherent_any(sc->parent_tag, 2466 stats_align, BCE_STATS_BLK_SZ, 2467 BUS_DMA_WAITOK | BUS_DMA_ZERO, 2468 &sc->stats_tag, &sc->stats_map, 2469 &sc->stats_block_paddr); 2470 if (sc->stats_block == NULL) { 2471 if_printf(ifp, "Could not allocate statistics block!\n"); 2472 return ENOMEM; 2473 } 2474 2475 /* 2476 * Allocate context block, if needed 2477 */ 2478 if (sc->ctx_pages != 0) { 2479 rc = bus_dma_tag_create(sc->parent_tag, BCM_PAGE_SIZE, 0, 2480 BUS_SPACE_MAXADDR, BUS_SPACE_MAXADDR, 2481 NULL, NULL, 2482 BCM_PAGE_SIZE, 1, BCM_PAGE_SIZE, 2483 0, &sc->ctx_tag); 2484 if (rc != 0) { 2485 if_printf(ifp, "Could not allocate " 2486 "context block DMA tag!\n"); 2487 return rc; 2488 } 2489 2490 for (i = 0; i < sc->ctx_pages; i++) { 2491 rc = bus_dmamem_alloc(sc->ctx_tag, 2492 (void **)&sc->ctx_block[i], 2493 BUS_DMA_WAITOK | BUS_DMA_ZERO | 2494 BUS_DMA_COHERENT, 2495 &sc->ctx_map[i]); 2496 if (rc != 0) { 2497 if_printf(ifp, "Could not allocate %dth context " 2498 "DMA memory!\n", i); 2499 return rc; 2500 } 2501 2502 rc = bus_dmamap_load(sc->ctx_tag, sc->ctx_map[i], 2503 sc->ctx_block[i], BCM_PAGE_SIZE, 2504 bce_dma_map_addr, &busaddr, 2505 BUS_DMA_WAITOK); 2506 if (rc != 0) { 2507 if (rc == EINPROGRESS) { 2508 panic("%s coherent memory loading " 2509 "is still in progress!", ifp->if_xname); 2510 } 2511 if_printf(ifp, "Could not map %dth context " 2512 "DMA memory!\n", i); 2513 bus_dmamem_free(sc->ctx_tag, sc->ctx_block[i], 2514 sc->ctx_map[i]); 2515 sc->ctx_block[i] = NULL; 2516 return rc; 2517 } 2518 sc->ctx_paddr[i] = busaddr; 2519 } 2520 } 2521 2522 sc->tx_rings = kmalloc_cachealign( 2523 sizeof(struct bce_tx_ring) * sc->tx_ring_cnt, M_DEVBUF, 2524 M_WAITOK | M_ZERO); 2525 for (i = 0; i < sc->tx_ring_cnt; ++i) { 2526 sc->tx_rings[i].sc = sc; 2527 if (i == 0) { 2528 sc->tx_rings[i].tx_cid = TX_CID; 2529 sc->tx_rings[i].tx_hw_cons = 2530 &sc->status_block->status_tx_quick_consumer_index0; 2531 } else { 2532 struct status_block_msix *sblk = 2533 (struct status_block_msix *) 2534 (((uint8_t *)(sc->status_block)) + 2535 (i * BCE_STATUS_BLK_MSIX_ALIGN)); 2536 2537 sc->tx_rings[i].tx_cid = TX_TSS_CID + i - 1; 2538 sc->tx_rings[i].tx_hw_cons = 2539 &sblk->status_tx_quick_consumer_index; 2540 } 2541 2542 rc = bce_create_tx_ring(&sc->tx_rings[i]); 2543 if (rc != 0) { 2544 device_printf(sc->bce_dev, 2545 "can't create %dth tx ring\n", i); 2546 return rc; 2547 } 2548 } 2549 2550 sc->rx_rings = kmalloc_cachealign( 2551 sizeof(struct bce_rx_ring) * sc->rx_ring_cnt, M_DEVBUF, 2552 M_WAITOK | M_ZERO); 2553 for (i = 0; i < sc->rx_ring_cnt; ++i) { 2554 sc->rx_rings[i].sc = sc; 2555 sc->rx_rings[i].idx = i; 2556 if (i == 0) { 2557 sc->rx_rings[i].rx_cid = RX_CID; 2558 sc->rx_rings[i].rx_hw_cons = 2559 &sc->status_block->status_rx_quick_consumer_index0; 2560 sc->rx_rings[i].hw_status_idx = 2561 &sc->status_block->status_idx; 2562 } else { 2563 struct status_block_msix *sblk = 2564 (struct status_block_msix *) 2565 (((uint8_t *)(sc->status_block)) + 2566 (i * BCE_STATUS_BLK_MSIX_ALIGN)); 2567 2568 sc->rx_rings[i].rx_cid = RX_RSS_CID + i - 1; 2569 sc->rx_rings[i].rx_hw_cons = 2570 &sblk->status_rx_quick_consumer_index; 2571 sc->rx_rings[i].hw_status_idx = &sblk->status_idx; 2572 } 2573 2574 rc = bce_create_rx_ring(&sc->rx_rings[i]); 2575 if (rc != 0) { 2576 device_printf(sc->bce_dev, 2577 "can't create %dth rx ring\n", i); 2578 return rc; 2579 } 2580 } 2581 2582 return 0; 2583 } 2584 2585 /****************************************************************************/ 2586 /* Firmware synchronization. */ 2587 /* */ 2588 /* Before performing certain events such as a chip reset, synchronize with */ 2589 /* the firmware first. */ 2590 /* */ 2591 /* Returns: */ 2592 /* 0 for success, positive value for failure. */ 2593 /****************************************************************************/ 2594 static int 2595 bce_fw_sync(struct bce_softc *sc, uint32_t msg_data) 2596 { 2597 int i, rc = 0; 2598 uint32_t val; 2599 2600 /* Don't waste any time if we've timed out before. */ 2601 if (sc->bce_fw_timed_out) 2602 return EBUSY; 2603 2604 /* Increment the message sequence number. */ 2605 sc->bce_fw_wr_seq++; 2606 msg_data |= sc->bce_fw_wr_seq; 2607 2608 /* Send the message to the bootcode driver mailbox. */ 2609 bce_shmem_wr(sc, BCE_DRV_MB, msg_data); 2610 2611 /* Wait for the bootcode to acknowledge the message. */ 2612 for (i = 0; i < FW_ACK_TIME_OUT_MS; i++) { 2613 /* Check for a response in the bootcode firmware mailbox. */ 2614 val = bce_shmem_rd(sc, BCE_FW_MB); 2615 if ((val & BCE_FW_MSG_ACK) == (msg_data & BCE_DRV_MSG_SEQ)) 2616 break; 2617 DELAY(1000); 2618 } 2619 2620 /* If we've timed out, tell the bootcode that we've stopped waiting. */ 2621 if ((val & BCE_FW_MSG_ACK) != (msg_data & BCE_DRV_MSG_SEQ) && 2622 (msg_data & BCE_DRV_MSG_DATA) != BCE_DRV_MSG_DATA_WAIT0) { 2623 if_printf(&sc->arpcom.ac_if, 2624 "Firmware synchronization timeout! " 2625 "msg_data = 0x%08X\n", msg_data); 2626 2627 msg_data &= ~BCE_DRV_MSG_CODE; 2628 msg_data |= BCE_DRV_MSG_CODE_FW_TIMEOUT; 2629 2630 bce_shmem_wr(sc, BCE_DRV_MB, msg_data); 2631 2632 sc->bce_fw_timed_out = 1; 2633 rc = EBUSY; 2634 } 2635 return rc; 2636 } 2637 2638 /****************************************************************************/ 2639 /* Load Receive Virtual 2 Physical (RV2P) processor firmware. */ 2640 /* */ 2641 /* Returns: */ 2642 /* Nothing. */ 2643 /****************************************************************************/ 2644 static void 2645 bce_load_rv2p_fw(struct bce_softc *sc, uint32_t *rv2p_code, 2646 uint32_t rv2p_code_len, uint32_t rv2p_proc) 2647 { 2648 int i; 2649 uint32_t val; 2650 2651 for (i = 0; i < rv2p_code_len; i += 8) { 2652 REG_WR(sc, BCE_RV2P_INSTR_HIGH, *rv2p_code); 2653 rv2p_code++; 2654 REG_WR(sc, BCE_RV2P_INSTR_LOW, *rv2p_code); 2655 rv2p_code++; 2656 2657 if (rv2p_proc == RV2P_PROC1) { 2658 val = (i / 8) | BCE_RV2P_PROC1_ADDR_CMD_RDWR; 2659 REG_WR(sc, BCE_RV2P_PROC1_ADDR_CMD, val); 2660 } else { 2661 val = (i / 8) | BCE_RV2P_PROC2_ADDR_CMD_RDWR; 2662 REG_WR(sc, BCE_RV2P_PROC2_ADDR_CMD, val); 2663 } 2664 } 2665 2666 /* Reset the processor, un-stall is done later. */ 2667 if (rv2p_proc == RV2P_PROC1) 2668 REG_WR(sc, BCE_RV2P_COMMAND, BCE_RV2P_COMMAND_PROC1_RESET); 2669 else 2670 REG_WR(sc, BCE_RV2P_COMMAND, BCE_RV2P_COMMAND_PROC2_RESET); 2671 } 2672 2673 /****************************************************************************/ 2674 /* Load RISC processor firmware. */ 2675 /* */ 2676 /* Loads firmware from the file if_bcefw.h into the scratchpad memory */ 2677 /* associated with a particular processor. */ 2678 /* */ 2679 /* Returns: */ 2680 /* Nothing. */ 2681 /****************************************************************************/ 2682 static void 2683 bce_load_cpu_fw(struct bce_softc *sc, struct cpu_reg *cpu_reg, 2684 struct fw_info *fw) 2685 { 2686 uint32_t offset; 2687 int j; 2688 2689 bce_halt_cpu(sc, cpu_reg); 2690 2691 /* Load the Text area. */ 2692 offset = cpu_reg->spad_base + (fw->text_addr - cpu_reg->mips_view_base); 2693 if (fw->text) { 2694 for (j = 0; j < (fw->text_len / 4); j++, offset += 4) 2695 REG_WR_IND(sc, offset, fw->text[j]); 2696 } 2697 2698 /* Load the Data area. */ 2699 offset = cpu_reg->spad_base + (fw->data_addr - cpu_reg->mips_view_base); 2700 if (fw->data) { 2701 for (j = 0; j < (fw->data_len / 4); j++, offset += 4) 2702 REG_WR_IND(sc, offset, fw->data[j]); 2703 } 2704 2705 /* Load the SBSS area. */ 2706 offset = cpu_reg->spad_base + (fw->sbss_addr - cpu_reg->mips_view_base); 2707 if (fw->sbss) { 2708 for (j = 0; j < (fw->sbss_len / 4); j++, offset += 4) 2709 REG_WR_IND(sc, offset, fw->sbss[j]); 2710 } 2711 2712 /* Load the BSS area. */ 2713 offset = cpu_reg->spad_base + (fw->bss_addr - cpu_reg->mips_view_base); 2714 if (fw->bss) { 2715 for (j = 0; j < (fw->bss_len/4); j++, offset += 4) 2716 REG_WR_IND(sc, offset, fw->bss[j]); 2717 } 2718 2719 /* Load the Read-Only area. */ 2720 offset = cpu_reg->spad_base + 2721 (fw->rodata_addr - cpu_reg->mips_view_base); 2722 if (fw->rodata) { 2723 for (j = 0; j < (fw->rodata_len / 4); j++, offset += 4) 2724 REG_WR_IND(sc, offset, fw->rodata[j]); 2725 } 2726 2727 /* Clear the pre-fetch instruction and set the FW start address. */ 2728 REG_WR_IND(sc, cpu_reg->inst, 0); 2729 REG_WR_IND(sc, cpu_reg->pc, fw->start_addr); 2730 } 2731 2732 /****************************************************************************/ 2733 /* Starts the RISC processor. */ 2734 /* */ 2735 /* Assumes the CPU starting address has already been set. */ 2736 /* */ 2737 /* Returns: */ 2738 /* Nothing. */ 2739 /****************************************************************************/ 2740 static void 2741 bce_start_cpu(struct bce_softc *sc, struct cpu_reg *cpu_reg) 2742 { 2743 uint32_t val; 2744 2745 /* Start the CPU. */ 2746 val = REG_RD_IND(sc, cpu_reg->mode); 2747 val &= ~cpu_reg->mode_value_halt; 2748 REG_WR_IND(sc, cpu_reg->state, cpu_reg->state_value_clear); 2749 REG_WR_IND(sc, cpu_reg->mode, val); 2750 } 2751 2752 /****************************************************************************/ 2753 /* Halts the RISC processor. */ 2754 /* */ 2755 /* Returns: */ 2756 /* Nothing. */ 2757 /****************************************************************************/ 2758 static void 2759 bce_halt_cpu(struct bce_softc *sc, struct cpu_reg *cpu_reg) 2760 { 2761 uint32_t val; 2762 2763 /* Halt the CPU. */ 2764 val = REG_RD_IND(sc, cpu_reg->mode); 2765 val |= cpu_reg->mode_value_halt; 2766 REG_WR_IND(sc, cpu_reg->mode, val); 2767 REG_WR_IND(sc, cpu_reg->state, cpu_reg->state_value_clear); 2768 } 2769 2770 /****************************************************************************/ 2771 /* Start the RX CPU. */ 2772 /* */ 2773 /* Returns: */ 2774 /* Nothing. */ 2775 /****************************************************************************/ 2776 static void 2777 bce_start_rxp_cpu(struct bce_softc *sc) 2778 { 2779 struct cpu_reg cpu_reg; 2780 2781 cpu_reg.mode = BCE_RXP_CPU_MODE; 2782 cpu_reg.mode_value_halt = BCE_RXP_CPU_MODE_SOFT_HALT; 2783 cpu_reg.mode_value_sstep = BCE_RXP_CPU_MODE_STEP_ENA; 2784 cpu_reg.state = BCE_RXP_CPU_STATE; 2785 cpu_reg.state_value_clear = 0xffffff; 2786 cpu_reg.gpr0 = BCE_RXP_CPU_REG_FILE; 2787 cpu_reg.evmask = BCE_RXP_CPU_EVENT_MASK; 2788 cpu_reg.pc = BCE_RXP_CPU_PROGRAM_COUNTER; 2789 cpu_reg.inst = BCE_RXP_CPU_INSTRUCTION; 2790 cpu_reg.bp = BCE_RXP_CPU_HW_BREAKPOINT; 2791 cpu_reg.spad_base = BCE_RXP_SCRATCH; 2792 cpu_reg.mips_view_base = 0x8000000; 2793 2794 bce_start_cpu(sc, &cpu_reg); 2795 } 2796 2797 /****************************************************************************/ 2798 /* Initialize the RX CPU. */ 2799 /* */ 2800 /* Returns: */ 2801 /* Nothing. */ 2802 /****************************************************************************/ 2803 static void 2804 bce_init_rxp_cpu(struct bce_softc *sc) 2805 { 2806 struct cpu_reg cpu_reg; 2807 struct fw_info fw; 2808 2809 cpu_reg.mode = BCE_RXP_CPU_MODE; 2810 cpu_reg.mode_value_halt = BCE_RXP_CPU_MODE_SOFT_HALT; 2811 cpu_reg.mode_value_sstep = BCE_RXP_CPU_MODE_STEP_ENA; 2812 cpu_reg.state = BCE_RXP_CPU_STATE; 2813 cpu_reg.state_value_clear = 0xffffff; 2814 cpu_reg.gpr0 = BCE_RXP_CPU_REG_FILE; 2815 cpu_reg.evmask = BCE_RXP_CPU_EVENT_MASK; 2816 cpu_reg.pc = BCE_RXP_CPU_PROGRAM_COUNTER; 2817 cpu_reg.inst = BCE_RXP_CPU_INSTRUCTION; 2818 cpu_reg.bp = BCE_RXP_CPU_HW_BREAKPOINT; 2819 cpu_reg.spad_base = BCE_RXP_SCRATCH; 2820 cpu_reg.mips_view_base = 0x8000000; 2821 2822 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 2823 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 2824 fw.ver_major = bce_RXP_b09FwReleaseMajor; 2825 fw.ver_minor = bce_RXP_b09FwReleaseMinor; 2826 fw.ver_fix = bce_RXP_b09FwReleaseFix; 2827 fw.start_addr = bce_RXP_b09FwStartAddr; 2828 2829 fw.text_addr = bce_RXP_b09FwTextAddr; 2830 fw.text_len = bce_RXP_b09FwTextLen; 2831 fw.text_index = 0; 2832 fw.text = bce_RXP_b09FwText; 2833 2834 fw.data_addr = bce_RXP_b09FwDataAddr; 2835 fw.data_len = bce_RXP_b09FwDataLen; 2836 fw.data_index = 0; 2837 fw.data = bce_RXP_b09FwData; 2838 2839 fw.sbss_addr = bce_RXP_b09FwSbssAddr; 2840 fw.sbss_len = bce_RXP_b09FwSbssLen; 2841 fw.sbss_index = 0; 2842 fw.sbss = bce_RXP_b09FwSbss; 2843 2844 fw.bss_addr = bce_RXP_b09FwBssAddr; 2845 fw.bss_len = bce_RXP_b09FwBssLen; 2846 fw.bss_index = 0; 2847 fw.bss = bce_RXP_b09FwBss; 2848 2849 fw.rodata_addr = bce_RXP_b09FwRodataAddr; 2850 fw.rodata_len = bce_RXP_b09FwRodataLen; 2851 fw.rodata_index = 0; 2852 fw.rodata = bce_RXP_b09FwRodata; 2853 } else { 2854 fw.ver_major = bce_RXP_b06FwReleaseMajor; 2855 fw.ver_minor = bce_RXP_b06FwReleaseMinor; 2856 fw.ver_fix = bce_RXP_b06FwReleaseFix; 2857 fw.start_addr = bce_RXP_b06FwStartAddr; 2858 2859 fw.text_addr = bce_RXP_b06FwTextAddr; 2860 fw.text_len = bce_RXP_b06FwTextLen; 2861 fw.text_index = 0; 2862 fw.text = bce_RXP_b06FwText; 2863 2864 fw.data_addr = bce_RXP_b06FwDataAddr; 2865 fw.data_len = bce_RXP_b06FwDataLen; 2866 fw.data_index = 0; 2867 fw.data = bce_RXP_b06FwData; 2868 2869 fw.sbss_addr = bce_RXP_b06FwSbssAddr; 2870 fw.sbss_len = bce_RXP_b06FwSbssLen; 2871 fw.sbss_index = 0; 2872 fw.sbss = bce_RXP_b06FwSbss; 2873 2874 fw.bss_addr = bce_RXP_b06FwBssAddr; 2875 fw.bss_len = bce_RXP_b06FwBssLen; 2876 fw.bss_index = 0; 2877 fw.bss = bce_RXP_b06FwBss; 2878 2879 fw.rodata_addr = bce_RXP_b06FwRodataAddr; 2880 fw.rodata_len = bce_RXP_b06FwRodataLen; 2881 fw.rodata_index = 0; 2882 fw.rodata = bce_RXP_b06FwRodata; 2883 } 2884 2885 bce_load_cpu_fw(sc, &cpu_reg, &fw); 2886 /* Delay RXP start until initialization is complete. */ 2887 } 2888 2889 /****************************************************************************/ 2890 /* Initialize the TX CPU. */ 2891 /* */ 2892 /* Returns: */ 2893 /* Nothing. */ 2894 /****************************************************************************/ 2895 static void 2896 bce_init_txp_cpu(struct bce_softc *sc) 2897 { 2898 struct cpu_reg cpu_reg; 2899 struct fw_info fw; 2900 2901 cpu_reg.mode = BCE_TXP_CPU_MODE; 2902 cpu_reg.mode_value_halt = BCE_TXP_CPU_MODE_SOFT_HALT; 2903 cpu_reg.mode_value_sstep = BCE_TXP_CPU_MODE_STEP_ENA; 2904 cpu_reg.state = BCE_TXP_CPU_STATE; 2905 cpu_reg.state_value_clear = 0xffffff; 2906 cpu_reg.gpr0 = BCE_TXP_CPU_REG_FILE; 2907 cpu_reg.evmask = BCE_TXP_CPU_EVENT_MASK; 2908 cpu_reg.pc = BCE_TXP_CPU_PROGRAM_COUNTER; 2909 cpu_reg.inst = BCE_TXP_CPU_INSTRUCTION; 2910 cpu_reg.bp = BCE_TXP_CPU_HW_BREAKPOINT; 2911 cpu_reg.spad_base = BCE_TXP_SCRATCH; 2912 cpu_reg.mips_view_base = 0x8000000; 2913 2914 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 2915 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 2916 fw.ver_major = bce_TXP_b09FwReleaseMajor; 2917 fw.ver_minor = bce_TXP_b09FwReleaseMinor; 2918 fw.ver_fix = bce_TXP_b09FwReleaseFix; 2919 fw.start_addr = bce_TXP_b09FwStartAddr; 2920 2921 fw.text_addr = bce_TXP_b09FwTextAddr; 2922 fw.text_len = bce_TXP_b09FwTextLen; 2923 fw.text_index = 0; 2924 fw.text = bce_TXP_b09FwText; 2925 2926 fw.data_addr = bce_TXP_b09FwDataAddr; 2927 fw.data_len = bce_TXP_b09FwDataLen; 2928 fw.data_index = 0; 2929 fw.data = bce_TXP_b09FwData; 2930 2931 fw.sbss_addr = bce_TXP_b09FwSbssAddr; 2932 fw.sbss_len = bce_TXP_b09FwSbssLen; 2933 fw.sbss_index = 0; 2934 fw.sbss = bce_TXP_b09FwSbss; 2935 2936 fw.bss_addr = bce_TXP_b09FwBssAddr; 2937 fw.bss_len = bce_TXP_b09FwBssLen; 2938 fw.bss_index = 0; 2939 fw.bss = bce_TXP_b09FwBss; 2940 2941 fw.rodata_addr = bce_TXP_b09FwRodataAddr; 2942 fw.rodata_len = bce_TXP_b09FwRodataLen; 2943 fw.rodata_index = 0; 2944 fw.rodata = bce_TXP_b09FwRodata; 2945 } else { 2946 fw.ver_major = bce_TXP_b06FwReleaseMajor; 2947 fw.ver_minor = bce_TXP_b06FwReleaseMinor; 2948 fw.ver_fix = bce_TXP_b06FwReleaseFix; 2949 fw.start_addr = bce_TXP_b06FwStartAddr; 2950 2951 fw.text_addr = bce_TXP_b06FwTextAddr; 2952 fw.text_len = bce_TXP_b06FwTextLen; 2953 fw.text_index = 0; 2954 fw.text = bce_TXP_b06FwText; 2955 2956 fw.data_addr = bce_TXP_b06FwDataAddr; 2957 fw.data_len = bce_TXP_b06FwDataLen; 2958 fw.data_index = 0; 2959 fw.data = bce_TXP_b06FwData; 2960 2961 fw.sbss_addr = bce_TXP_b06FwSbssAddr; 2962 fw.sbss_len = bce_TXP_b06FwSbssLen; 2963 fw.sbss_index = 0; 2964 fw.sbss = bce_TXP_b06FwSbss; 2965 2966 fw.bss_addr = bce_TXP_b06FwBssAddr; 2967 fw.bss_len = bce_TXP_b06FwBssLen; 2968 fw.bss_index = 0; 2969 fw.bss = bce_TXP_b06FwBss; 2970 2971 fw.rodata_addr = bce_TXP_b06FwRodataAddr; 2972 fw.rodata_len = bce_TXP_b06FwRodataLen; 2973 fw.rodata_index = 0; 2974 fw.rodata = bce_TXP_b06FwRodata; 2975 } 2976 2977 bce_load_cpu_fw(sc, &cpu_reg, &fw); 2978 bce_start_cpu(sc, &cpu_reg); 2979 } 2980 2981 /****************************************************************************/ 2982 /* Initialize the TPAT CPU. */ 2983 /* */ 2984 /* Returns: */ 2985 /* Nothing. */ 2986 /****************************************************************************/ 2987 static void 2988 bce_init_tpat_cpu(struct bce_softc *sc) 2989 { 2990 struct cpu_reg cpu_reg; 2991 struct fw_info fw; 2992 2993 cpu_reg.mode = BCE_TPAT_CPU_MODE; 2994 cpu_reg.mode_value_halt = BCE_TPAT_CPU_MODE_SOFT_HALT; 2995 cpu_reg.mode_value_sstep = BCE_TPAT_CPU_MODE_STEP_ENA; 2996 cpu_reg.state = BCE_TPAT_CPU_STATE; 2997 cpu_reg.state_value_clear = 0xffffff; 2998 cpu_reg.gpr0 = BCE_TPAT_CPU_REG_FILE; 2999 cpu_reg.evmask = BCE_TPAT_CPU_EVENT_MASK; 3000 cpu_reg.pc = BCE_TPAT_CPU_PROGRAM_COUNTER; 3001 cpu_reg.inst = BCE_TPAT_CPU_INSTRUCTION; 3002 cpu_reg.bp = BCE_TPAT_CPU_HW_BREAKPOINT; 3003 cpu_reg.spad_base = BCE_TPAT_SCRATCH; 3004 cpu_reg.mips_view_base = 0x8000000; 3005 3006 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 3007 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 3008 fw.ver_major = bce_TPAT_b09FwReleaseMajor; 3009 fw.ver_minor = bce_TPAT_b09FwReleaseMinor; 3010 fw.ver_fix = bce_TPAT_b09FwReleaseFix; 3011 fw.start_addr = bce_TPAT_b09FwStartAddr; 3012 3013 fw.text_addr = bce_TPAT_b09FwTextAddr; 3014 fw.text_len = bce_TPAT_b09FwTextLen; 3015 fw.text_index = 0; 3016 fw.text = bce_TPAT_b09FwText; 3017 3018 fw.data_addr = bce_TPAT_b09FwDataAddr; 3019 fw.data_len = bce_TPAT_b09FwDataLen; 3020 fw.data_index = 0; 3021 fw.data = bce_TPAT_b09FwData; 3022 3023 fw.sbss_addr = bce_TPAT_b09FwSbssAddr; 3024 fw.sbss_len = bce_TPAT_b09FwSbssLen; 3025 fw.sbss_index = 0; 3026 fw.sbss = bce_TPAT_b09FwSbss; 3027 3028 fw.bss_addr = bce_TPAT_b09FwBssAddr; 3029 fw.bss_len = bce_TPAT_b09FwBssLen; 3030 fw.bss_index = 0; 3031 fw.bss = bce_TPAT_b09FwBss; 3032 3033 fw.rodata_addr = bce_TPAT_b09FwRodataAddr; 3034 fw.rodata_len = bce_TPAT_b09FwRodataLen; 3035 fw.rodata_index = 0; 3036 fw.rodata = bce_TPAT_b09FwRodata; 3037 } else { 3038 fw.ver_major = bce_TPAT_b06FwReleaseMajor; 3039 fw.ver_minor = bce_TPAT_b06FwReleaseMinor; 3040 fw.ver_fix = bce_TPAT_b06FwReleaseFix; 3041 fw.start_addr = bce_TPAT_b06FwStartAddr; 3042 3043 fw.text_addr = bce_TPAT_b06FwTextAddr; 3044 fw.text_len = bce_TPAT_b06FwTextLen; 3045 fw.text_index = 0; 3046 fw.text = bce_TPAT_b06FwText; 3047 3048 fw.data_addr = bce_TPAT_b06FwDataAddr; 3049 fw.data_len = bce_TPAT_b06FwDataLen; 3050 fw.data_index = 0; 3051 fw.data = bce_TPAT_b06FwData; 3052 3053 fw.sbss_addr = bce_TPAT_b06FwSbssAddr; 3054 fw.sbss_len = bce_TPAT_b06FwSbssLen; 3055 fw.sbss_index = 0; 3056 fw.sbss = bce_TPAT_b06FwSbss; 3057 3058 fw.bss_addr = bce_TPAT_b06FwBssAddr; 3059 fw.bss_len = bce_TPAT_b06FwBssLen; 3060 fw.bss_index = 0; 3061 fw.bss = bce_TPAT_b06FwBss; 3062 3063 fw.rodata_addr = bce_TPAT_b06FwRodataAddr; 3064 fw.rodata_len = bce_TPAT_b06FwRodataLen; 3065 fw.rodata_index = 0; 3066 fw.rodata = bce_TPAT_b06FwRodata; 3067 } 3068 3069 bce_load_cpu_fw(sc, &cpu_reg, &fw); 3070 bce_start_cpu(sc, &cpu_reg); 3071 } 3072 3073 /****************************************************************************/ 3074 /* Initialize the CP CPU. */ 3075 /* */ 3076 /* Returns: */ 3077 /* Nothing. */ 3078 /****************************************************************************/ 3079 static void 3080 bce_init_cp_cpu(struct bce_softc *sc) 3081 { 3082 struct cpu_reg cpu_reg; 3083 struct fw_info fw; 3084 3085 cpu_reg.mode = BCE_CP_CPU_MODE; 3086 cpu_reg.mode_value_halt = BCE_CP_CPU_MODE_SOFT_HALT; 3087 cpu_reg.mode_value_sstep = BCE_CP_CPU_MODE_STEP_ENA; 3088 cpu_reg.state = BCE_CP_CPU_STATE; 3089 cpu_reg.state_value_clear = 0xffffff; 3090 cpu_reg.gpr0 = BCE_CP_CPU_REG_FILE; 3091 cpu_reg.evmask = BCE_CP_CPU_EVENT_MASK; 3092 cpu_reg.pc = BCE_CP_CPU_PROGRAM_COUNTER; 3093 cpu_reg.inst = BCE_CP_CPU_INSTRUCTION; 3094 cpu_reg.bp = BCE_CP_CPU_HW_BREAKPOINT; 3095 cpu_reg.spad_base = BCE_CP_SCRATCH; 3096 cpu_reg.mips_view_base = 0x8000000; 3097 3098 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 3099 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 3100 fw.ver_major = bce_CP_b09FwReleaseMajor; 3101 fw.ver_minor = bce_CP_b09FwReleaseMinor; 3102 fw.ver_fix = bce_CP_b09FwReleaseFix; 3103 fw.start_addr = bce_CP_b09FwStartAddr; 3104 3105 fw.text_addr = bce_CP_b09FwTextAddr; 3106 fw.text_len = bce_CP_b09FwTextLen; 3107 fw.text_index = 0; 3108 fw.text = bce_CP_b09FwText; 3109 3110 fw.data_addr = bce_CP_b09FwDataAddr; 3111 fw.data_len = bce_CP_b09FwDataLen; 3112 fw.data_index = 0; 3113 fw.data = bce_CP_b09FwData; 3114 3115 fw.sbss_addr = bce_CP_b09FwSbssAddr; 3116 fw.sbss_len = bce_CP_b09FwSbssLen; 3117 fw.sbss_index = 0; 3118 fw.sbss = bce_CP_b09FwSbss; 3119 3120 fw.bss_addr = bce_CP_b09FwBssAddr; 3121 fw.bss_len = bce_CP_b09FwBssLen; 3122 fw.bss_index = 0; 3123 fw.bss = bce_CP_b09FwBss; 3124 3125 fw.rodata_addr = bce_CP_b09FwRodataAddr; 3126 fw.rodata_len = bce_CP_b09FwRodataLen; 3127 fw.rodata_index = 0; 3128 fw.rodata = bce_CP_b09FwRodata; 3129 } else { 3130 fw.ver_major = bce_CP_b06FwReleaseMajor; 3131 fw.ver_minor = bce_CP_b06FwReleaseMinor; 3132 fw.ver_fix = bce_CP_b06FwReleaseFix; 3133 fw.start_addr = bce_CP_b06FwStartAddr; 3134 3135 fw.text_addr = bce_CP_b06FwTextAddr; 3136 fw.text_len = bce_CP_b06FwTextLen; 3137 fw.text_index = 0; 3138 fw.text = bce_CP_b06FwText; 3139 3140 fw.data_addr = bce_CP_b06FwDataAddr; 3141 fw.data_len = bce_CP_b06FwDataLen; 3142 fw.data_index = 0; 3143 fw.data = bce_CP_b06FwData; 3144 3145 fw.sbss_addr = bce_CP_b06FwSbssAddr; 3146 fw.sbss_len = bce_CP_b06FwSbssLen; 3147 fw.sbss_index = 0; 3148 fw.sbss = bce_CP_b06FwSbss; 3149 3150 fw.bss_addr = bce_CP_b06FwBssAddr; 3151 fw.bss_len = bce_CP_b06FwBssLen; 3152 fw.bss_index = 0; 3153 fw.bss = bce_CP_b06FwBss; 3154 3155 fw.rodata_addr = bce_CP_b06FwRodataAddr; 3156 fw.rodata_len = bce_CP_b06FwRodataLen; 3157 fw.rodata_index = 0; 3158 fw.rodata = bce_CP_b06FwRodata; 3159 } 3160 3161 bce_load_cpu_fw(sc, &cpu_reg, &fw); 3162 bce_start_cpu(sc, &cpu_reg); 3163 } 3164 3165 /****************************************************************************/ 3166 /* Initialize the COM CPU. */ 3167 /* */ 3168 /* Returns: */ 3169 /* Nothing. */ 3170 /****************************************************************************/ 3171 static void 3172 bce_init_com_cpu(struct bce_softc *sc) 3173 { 3174 struct cpu_reg cpu_reg; 3175 struct fw_info fw; 3176 3177 cpu_reg.mode = BCE_COM_CPU_MODE; 3178 cpu_reg.mode_value_halt = BCE_COM_CPU_MODE_SOFT_HALT; 3179 cpu_reg.mode_value_sstep = BCE_COM_CPU_MODE_STEP_ENA; 3180 cpu_reg.state = BCE_COM_CPU_STATE; 3181 cpu_reg.state_value_clear = 0xffffff; 3182 cpu_reg.gpr0 = BCE_COM_CPU_REG_FILE; 3183 cpu_reg.evmask = BCE_COM_CPU_EVENT_MASK; 3184 cpu_reg.pc = BCE_COM_CPU_PROGRAM_COUNTER; 3185 cpu_reg.inst = BCE_COM_CPU_INSTRUCTION; 3186 cpu_reg.bp = BCE_COM_CPU_HW_BREAKPOINT; 3187 cpu_reg.spad_base = BCE_COM_SCRATCH; 3188 cpu_reg.mips_view_base = 0x8000000; 3189 3190 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 3191 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 3192 fw.ver_major = bce_COM_b09FwReleaseMajor; 3193 fw.ver_minor = bce_COM_b09FwReleaseMinor; 3194 fw.ver_fix = bce_COM_b09FwReleaseFix; 3195 fw.start_addr = bce_COM_b09FwStartAddr; 3196 3197 fw.text_addr = bce_COM_b09FwTextAddr; 3198 fw.text_len = bce_COM_b09FwTextLen; 3199 fw.text_index = 0; 3200 fw.text = bce_COM_b09FwText; 3201 3202 fw.data_addr = bce_COM_b09FwDataAddr; 3203 fw.data_len = bce_COM_b09FwDataLen; 3204 fw.data_index = 0; 3205 fw.data = bce_COM_b09FwData; 3206 3207 fw.sbss_addr = bce_COM_b09FwSbssAddr; 3208 fw.sbss_len = bce_COM_b09FwSbssLen; 3209 fw.sbss_index = 0; 3210 fw.sbss = bce_COM_b09FwSbss; 3211 3212 fw.bss_addr = bce_COM_b09FwBssAddr; 3213 fw.bss_len = bce_COM_b09FwBssLen; 3214 fw.bss_index = 0; 3215 fw.bss = bce_COM_b09FwBss; 3216 3217 fw.rodata_addr = bce_COM_b09FwRodataAddr; 3218 fw.rodata_len = bce_COM_b09FwRodataLen; 3219 fw.rodata_index = 0; 3220 fw.rodata = bce_COM_b09FwRodata; 3221 } else { 3222 fw.ver_major = bce_COM_b06FwReleaseMajor; 3223 fw.ver_minor = bce_COM_b06FwReleaseMinor; 3224 fw.ver_fix = bce_COM_b06FwReleaseFix; 3225 fw.start_addr = bce_COM_b06FwStartAddr; 3226 3227 fw.text_addr = bce_COM_b06FwTextAddr; 3228 fw.text_len = bce_COM_b06FwTextLen; 3229 fw.text_index = 0; 3230 fw.text = bce_COM_b06FwText; 3231 3232 fw.data_addr = bce_COM_b06FwDataAddr; 3233 fw.data_len = bce_COM_b06FwDataLen; 3234 fw.data_index = 0; 3235 fw.data = bce_COM_b06FwData; 3236 3237 fw.sbss_addr = bce_COM_b06FwSbssAddr; 3238 fw.sbss_len = bce_COM_b06FwSbssLen; 3239 fw.sbss_index = 0; 3240 fw.sbss = bce_COM_b06FwSbss; 3241 3242 fw.bss_addr = bce_COM_b06FwBssAddr; 3243 fw.bss_len = bce_COM_b06FwBssLen; 3244 fw.bss_index = 0; 3245 fw.bss = bce_COM_b06FwBss; 3246 3247 fw.rodata_addr = bce_COM_b06FwRodataAddr; 3248 fw.rodata_len = bce_COM_b06FwRodataLen; 3249 fw.rodata_index = 0; 3250 fw.rodata = bce_COM_b06FwRodata; 3251 } 3252 3253 bce_load_cpu_fw(sc, &cpu_reg, &fw); 3254 bce_start_cpu(sc, &cpu_reg); 3255 } 3256 3257 /****************************************************************************/ 3258 /* Initialize the RV2P, RX, TX, TPAT, COM, and CP CPUs. */ 3259 /* */ 3260 /* Loads the firmware for each CPU and starts the CPU. */ 3261 /* */ 3262 /* Returns: */ 3263 /* Nothing. */ 3264 /****************************************************************************/ 3265 static void 3266 bce_init_cpus(struct bce_softc *sc) 3267 { 3268 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 3269 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 3270 if (BCE_CHIP_REV(sc) == BCE_CHIP_REV_Ax) { 3271 bce_load_rv2p_fw(sc, bce_xi90_rv2p_proc1, 3272 sizeof(bce_xi90_rv2p_proc1), RV2P_PROC1); 3273 bce_load_rv2p_fw(sc, bce_xi90_rv2p_proc2, 3274 sizeof(bce_xi90_rv2p_proc2), RV2P_PROC2); 3275 } else { 3276 bce_load_rv2p_fw(sc, bce_xi_rv2p_proc1, 3277 sizeof(bce_xi_rv2p_proc1), RV2P_PROC1); 3278 bce_load_rv2p_fw(sc, bce_xi_rv2p_proc2, 3279 sizeof(bce_xi_rv2p_proc2), RV2P_PROC2); 3280 } 3281 } else { 3282 bce_load_rv2p_fw(sc, bce_rv2p_proc1, 3283 sizeof(bce_rv2p_proc1), RV2P_PROC1); 3284 bce_load_rv2p_fw(sc, bce_rv2p_proc2, 3285 sizeof(bce_rv2p_proc2), RV2P_PROC2); 3286 } 3287 3288 bce_init_rxp_cpu(sc); 3289 bce_init_txp_cpu(sc); 3290 bce_init_tpat_cpu(sc); 3291 bce_init_com_cpu(sc); 3292 bce_init_cp_cpu(sc); 3293 } 3294 3295 /****************************************************************************/ 3296 /* Initialize context memory. */ 3297 /* */ 3298 /* Clears the memory associated with each Context ID (CID). */ 3299 /* */ 3300 /* Returns: */ 3301 /* Nothing. */ 3302 /****************************************************************************/ 3303 static int 3304 bce_init_ctx(struct bce_softc *sc) 3305 { 3306 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 3307 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 3308 /* DRC: Replace this constant value with a #define. */ 3309 int i, retry_cnt = 10; 3310 uint32_t val; 3311 3312 /* 3313 * BCM5709 context memory may be cached 3314 * in host memory so prepare the host memory 3315 * for access. 3316 */ 3317 val = BCE_CTX_COMMAND_ENABLED | BCE_CTX_COMMAND_MEM_INIT | 3318 (1 << 12); 3319 val |= (BCM_PAGE_BITS - 8) << 16; 3320 REG_WR(sc, BCE_CTX_COMMAND, val); 3321 3322 /* Wait for mem init command to complete. */ 3323 for (i = 0; i < retry_cnt; i++) { 3324 val = REG_RD(sc, BCE_CTX_COMMAND); 3325 if (!(val & BCE_CTX_COMMAND_MEM_INIT)) 3326 break; 3327 DELAY(2); 3328 } 3329 if (i == retry_cnt) { 3330 device_printf(sc->bce_dev, 3331 "Context memory initialization failed!\n"); 3332 return ETIMEDOUT; 3333 } 3334 3335 for (i = 0; i < sc->ctx_pages; i++) { 3336 int j; 3337 3338 /* 3339 * Set the physical address of the context 3340 * memory cache. 3341 */ 3342 REG_WR(sc, BCE_CTX_HOST_PAGE_TBL_DATA0, 3343 BCE_ADDR_LO(sc->ctx_paddr[i] & 0xfffffff0) | 3344 BCE_CTX_HOST_PAGE_TBL_DATA0_VALID); 3345 REG_WR(sc, BCE_CTX_HOST_PAGE_TBL_DATA1, 3346 BCE_ADDR_HI(sc->ctx_paddr[i])); 3347 REG_WR(sc, BCE_CTX_HOST_PAGE_TBL_CTRL, 3348 i | BCE_CTX_HOST_PAGE_TBL_CTRL_WRITE_REQ); 3349 3350 /* 3351 * Verify that the context memory write was successful. 3352 */ 3353 for (j = 0; j < retry_cnt; j++) { 3354 val = REG_RD(sc, BCE_CTX_HOST_PAGE_TBL_CTRL); 3355 if ((val & 3356 BCE_CTX_HOST_PAGE_TBL_CTRL_WRITE_REQ) == 0) 3357 break; 3358 DELAY(5); 3359 } 3360 if (j == retry_cnt) { 3361 device_printf(sc->bce_dev, 3362 "Failed to initialize context page!\n"); 3363 return ETIMEDOUT; 3364 } 3365 } 3366 } else { 3367 uint32_t vcid_addr, offset; 3368 3369 /* 3370 * For the 5706/5708, context memory is local to 3371 * the controller, so initialize the controller 3372 * context memory. 3373 */ 3374 3375 vcid_addr = GET_CID_ADDR(96); 3376 while (vcid_addr) { 3377 vcid_addr -= PHY_CTX_SIZE; 3378 3379 REG_WR(sc, BCE_CTX_VIRT_ADDR, 0); 3380 REG_WR(sc, BCE_CTX_PAGE_TBL, vcid_addr); 3381 3382 for (offset = 0; offset < PHY_CTX_SIZE; offset += 4) 3383 CTX_WR(sc, 0x00, offset, 0); 3384 3385 REG_WR(sc, BCE_CTX_VIRT_ADDR, vcid_addr); 3386 REG_WR(sc, BCE_CTX_PAGE_TBL, vcid_addr); 3387 } 3388 } 3389 return 0; 3390 } 3391 3392 /****************************************************************************/ 3393 /* Fetch the permanent MAC address of the controller. */ 3394 /* */ 3395 /* Returns: */ 3396 /* Nothing. */ 3397 /****************************************************************************/ 3398 static void 3399 bce_get_mac_addr(struct bce_softc *sc) 3400 { 3401 uint32_t mac_lo = 0, mac_hi = 0; 3402 3403 /* 3404 * The NetXtreme II bootcode populates various NIC 3405 * power-on and runtime configuration items in a 3406 * shared memory area. The factory configured MAC 3407 * address is available from both NVRAM and the 3408 * shared memory area so we'll read the value from 3409 * shared memory for speed. 3410 */ 3411 3412 mac_hi = bce_shmem_rd(sc, BCE_PORT_HW_CFG_MAC_UPPER); 3413 mac_lo = bce_shmem_rd(sc, BCE_PORT_HW_CFG_MAC_LOWER); 3414 3415 if (mac_lo == 0 && mac_hi == 0) { 3416 if_printf(&sc->arpcom.ac_if, "Invalid Ethernet address!\n"); 3417 } else { 3418 sc->eaddr[0] = (u_char)(mac_hi >> 8); 3419 sc->eaddr[1] = (u_char)(mac_hi >> 0); 3420 sc->eaddr[2] = (u_char)(mac_lo >> 24); 3421 sc->eaddr[3] = (u_char)(mac_lo >> 16); 3422 sc->eaddr[4] = (u_char)(mac_lo >> 8); 3423 sc->eaddr[5] = (u_char)(mac_lo >> 0); 3424 } 3425 } 3426 3427 /****************************************************************************/ 3428 /* Program the MAC address. */ 3429 /* */ 3430 /* Returns: */ 3431 /* Nothing. */ 3432 /****************************************************************************/ 3433 static void 3434 bce_set_mac_addr(struct bce_softc *sc) 3435 { 3436 const uint8_t *mac_addr = sc->eaddr; 3437 uint32_t val; 3438 3439 val = (mac_addr[0] << 8) | mac_addr[1]; 3440 REG_WR(sc, BCE_EMAC_MAC_MATCH0, val); 3441 3442 val = (mac_addr[2] << 24) | 3443 (mac_addr[3] << 16) | 3444 (mac_addr[4] << 8) | 3445 mac_addr[5]; 3446 REG_WR(sc, BCE_EMAC_MAC_MATCH1, val); 3447 } 3448 3449 /****************************************************************************/ 3450 /* Stop the controller. */ 3451 /* */ 3452 /* Returns: */ 3453 /* Nothing. */ 3454 /****************************************************************************/ 3455 static void 3456 bce_stop(struct bce_softc *sc) 3457 { 3458 struct ifnet *ifp = &sc->arpcom.ac_if; 3459 int i; 3460 3461 ASSERT_IFNET_SERIALIZED_ALL(ifp); 3462 3463 callout_stop(&sc->bce_tick_callout); 3464 3465 /* Disable the transmit/receive blocks. */ 3466 REG_WR(sc, BCE_MISC_ENABLE_CLR_BITS, BCE_MISC_ENABLE_CLR_DEFAULT); 3467 REG_RD(sc, BCE_MISC_ENABLE_CLR_BITS); 3468 DELAY(20); 3469 3470 bce_disable_intr(sc); 3471 3472 ifp->if_flags &= ~IFF_RUNNING; 3473 for (i = 0; i < sc->tx_ring_cnt; ++i) { 3474 ifsq_clr_oactive(sc->tx_rings[i].ifsq); 3475 ifsq_watchdog_stop(&sc->tx_rings[i].tx_watchdog); 3476 } 3477 3478 /* Free the RX lists. */ 3479 for (i = 0; i < sc->rx_ring_cnt; ++i) 3480 bce_free_rx_chain(&sc->rx_rings[i]); 3481 3482 /* Free TX buffers. */ 3483 for (i = 0; i < sc->tx_ring_cnt; ++i) 3484 bce_free_tx_chain(&sc->tx_rings[i]); 3485 3486 sc->bce_link = 0; 3487 sc->bce_coalchg_mask = 0; 3488 } 3489 3490 static int 3491 bce_reset(struct bce_softc *sc, uint32_t reset_code) 3492 { 3493 uint32_t val; 3494 int i, rc = 0; 3495 3496 /* Wait for pending PCI transactions to complete. */ 3497 REG_WR(sc, BCE_MISC_ENABLE_CLR_BITS, 3498 BCE_MISC_ENABLE_CLR_BITS_TX_DMA_ENABLE | 3499 BCE_MISC_ENABLE_CLR_BITS_DMA_ENGINE_ENABLE | 3500 BCE_MISC_ENABLE_CLR_BITS_RX_DMA_ENABLE | 3501 BCE_MISC_ENABLE_CLR_BITS_HOST_COALESCE_ENABLE); 3502 val = REG_RD(sc, BCE_MISC_ENABLE_CLR_BITS); 3503 DELAY(5); 3504 3505 /* Disable DMA */ 3506 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 3507 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 3508 val = REG_RD(sc, BCE_MISC_NEW_CORE_CTL); 3509 val &= ~BCE_MISC_NEW_CORE_CTL_DMA_ENABLE; 3510 REG_WR(sc, BCE_MISC_NEW_CORE_CTL, val); 3511 } 3512 3513 /* Assume bootcode is running. */ 3514 sc->bce_fw_timed_out = 0; 3515 sc->bce_drv_cardiac_arrest = 0; 3516 3517 /* Give the firmware a chance to prepare for the reset. */ 3518 rc = bce_fw_sync(sc, BCE_DRV_MSG_DATA_WAIT0 | reset_code); 3519 if (rc) { 3520 if_printf(&sc->arpcom.ac_if, 3521 "Firmware is not ready for reset\n"); 3522 return rc; 3523 } 3524 3525 /* Set a firmware reminder that this is a soft reset. */ 3526 bce_shmem_wr(sc, BCE_DRV_RESET_SIGNATURE, 3527 BCE_DRV_RESET_SIGNATURE_MAGIC); 3528 3529 /* Dummy read to force the chip to complete all current transactions. */ 3530 val = REG_RD(sc, BCE_MISC_ID); 3531 3532 /* Chip reset. */ 3533 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 3534 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 3535 REG_WR(sc, BCE_MISC_COMMAND, BCE_MISC_COMMAND_SW_RESET); 3536 REG_RD(sc, BCE_MISC_COMMAND); 3537 DELAY(5); 3538 3539 val = BCE_PCICFG_MISC_CONFIG_REG_WINDOW_ENA | 3540 BCE_PCICFG_MISC_CONFIG_TARGET_MB_WORD_SWAP; 3541 3542 pci_write_config(sc->bce_dev, BCE_PCICFG_MISC_CONFIG, val, 4); 3543 } else { 3544 val = BCE_PCICFG_MISC_CONFIG_CORE_RST_REQ | 3545 BCE_PCICFG_MISC_CONFIG_REG_WINDOW_ENA | 3546 BCE_PCICFG_MISC_CONFIG_TARGET_MB_WORD_SWAP; 3547 REG_WR(sc, BCE_PCICFG_MISC_CONFIG, val); 3548 3549 /* Allow up to 30us for reset to complete. */ 3550 for (i = 0; i < 10; i++) { 3551 val = REG_RD(sc, BCE_PCICFG_MISC_CONFIG); 3552 if ((val & (BCE_PCICFG_MISC_CONFIG_CORE_RST_REQ | 3553 BCE_PCICFG_MISC_CONFIG_CORE_RST_BSY)) == 0) 3554 break; 3555 DELAY(10); 3556 } 3557 3558 /* Check that reset completed successfully. */ 3559 if (val & (BCE_PCICFG_MISC_CONFIG_CORE_RST_REQ | 3560 BCE_PCICFG_MISC_CONFIG_CORE_RST_BSY)) { 3561 if_printf(&sc->arpcom.ac_if, "Reset failed!\n"); 3562 return EBUSY; 3563 } 3564 } 3565 3566 /* Make sure byte swapping is properly configured. */ 3567 val = REG_RD(sc, BCE_PCI_SWAP_DIAG0); 3568 if (val != 0x01020304) { 3569 if_printf(&sc->arpcom.ac_if, "Byte swap is incorrect!\n"); 3570 return ENODEV; 3571 } 3572 3573 /* Just completed a reset, assume that firmware is running again. */ 3574 sc->bce_fw_timed_out = 0; 3575 sc->bce_drv_cardiac_arrest = 0; 3576 3577 /* Wait for the firmware to finish its initialization. */ 3578 rc = bce_fw_sync(sc, BCE_DRV_MSG_DATA_WAIT1 | reset_code); 3579 if (rc) { 3580 if_printf(&sc->arpcom.ac_if, 3581 "Firmware did not complete initialization!\n"); 3582 } 3583 3584 if (sc->bce_irq_type == PCI_INTR_TYPE_MSIX) { 3585 bce_setup_msix_table(sc); 3586 /* Prevent MSIX table reads and write from timing out */ 3587 REG_WR(sc, BCE_MISC_ECO_HW_CTL, 3588 BCE_MISC_ECO_HW_CTL_LARGE_GRC_TMOUT_EN); 3589 3590 } 3591 return rc; 3592 } 3593 3594 static int 3595 bce_chipinit(struct bce_softc *sc) 3596 { 3597 uint32_t val; 3598 int rc = 0; 3599 3600 /* Make sure the interrupt is not active. */ 3601 REG_WR(sc, BCE_PCICFG_INT_ACK_CMD, BCE_PCICFG_INT_ACK_CMD_MASK_INT); 3602 REG_RD(sc, BCE_PCICFG_INT_ACK_CMD); 3603 3604 /* 3605 * Initialize DMA byte/word swapping, configure the number of DMA 3606 * channels and PCI clock compensation delay. 3607 */ 3608 val = BCE_DMA_CONFIG_DATA_BYTE_SWAP | 3609 BCE_DMA_CONFIG_DATA_WORD_SWAP | 3610 #if BYTE_ORDER == BIG_ENDIAN 3611 BCE_DMA_CONFIG_CNTL_BYTE_SWAP | 3612 #endif 3613 BCE_DMA_CONFIG_CNTL_WORD_SWAP | 3614 DMA_READ_CHANS << 12 | 3615 DMA_WRITE_CHANS << 16; 3616 3617 val |= (0x2 << 20) | BCE_DMA_CONFIG_CNTL_PCI_COMP_DLY; 3618 3619 if ((sc->bce_flags & BCE_PCIX_FLAG) && sc->bus_speed_mhz == 133) 3620 val |= BCE_DMA_CONFIG_PCI_FAST_CLK_CMP; 3621 3622 /* 3623 * This setting resolves a problem observed on certain Intel PCI 3624 * chipsets that cannot handle multiple outstanding DMA operations. 3625 * See errata E9_5706A1_65. 3626 */ 3627 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5706 && 3628 BCE_CHIP_ID(sc) != BCE_CHIP_ID_5706_A0 && 3629 !(sc->bce_flags & BCE_PCIX_FLAG)) 3630 val |= BCE_DMA_CONFIG_CNTL_PING_PONG_DMA; 3631 3632 REG_WR(sc, BCE_DMA_CONFIG, val); 3633 3634 /* Enable the RX_V2P and Context state machines before access. */ 3635 REG_WR(sc, BCE_MISC_ENABLE_SET_BITS, 3636 BCE_MISC_ENABLE_SET_BITS_HOST_COALESCE_ENABLE | 3637 BCE_MISC_ENABLE_STATUS_BITS_RX_V2P_ENABLE | 3638 BCE_MISC_ENABLE_STATUS_BITS_CONTEXT_ENABLE); 3639 3640 /* Initialize context mapping and zero out the quick contexts. */ 3641 rc = bce_init_ctx(sc); 3642 if (rc != 0) 3643 return rc; 3644 3645 /* Initialize the on-boards CPUs */ 3646 bce_init_cpus(sc); 3647 3648 /* Enable management frames (NC-SI) to flow to the MCP. */ 3649 if (sc->bce_flags & BCE_MFW_ENABLE_FLAG) { 3650 val = REG_RD(sc, BCE_RPM_MGMT_PKT_CTRL) | 3651 BCE_RPM_MGMT_PKT_CTRL_MGMT_EN; 3652 REG_WR(sc, BCE_RPM_MGMT_PKT_CTRL, val); 3653 } 3654 3655 /* Prepare NVRAM for access. */ 3656 rc = bce_init_nvram(sc); 3657 if (rc != 0) 3658 return rc; 3659 3660 /* Set the kernel bypass block size */ 3661 val = REG_RD(sc, BCE_MQ_CONFIG); 3662 val &= ~BCE_MQ_CONFIG_KNL_BYP_BLK_SIZE; 3663 val |= BCE_MQ_CONFIG_KNL_BYP_BLK_SIZE_256; 3664 3665 /* Enable bins used on the 5709/5716. */ 3666 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 3667 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 3668 val |= BCE_MQ_CONFIG_BIN_MQ_MODE; 3669 if (BCE_CHIP_ID(sc) == BCE_CHIP_ID_5709_A1) 3670 val |= BCE_MQ_CONFIG_HALT_DIS; 3671 } 3672 3673 REG_WR(sc, BCE_MQ_CONFIG, val); 3674 3675 val = 0x10000 + (MAX_CID_CNT * MB_KERNEL_CTX_SIZE); 3676 REG_WR(sc, BCE_MQ_KNL_BYP_WIND_START, val); 3677 REG_WR(sc, BCE_MQ_KNL_WIND_END, val); 3678 3679 /* Set the page size and clear the RV2P processor stall bits. */ 3680 val = (BCM_PAGE_BITS - 8) << 24; 3681 REG_WR(sc, BCE_RV2P_CONFIG, val); 3682 3683 /* Configure page size. */ 3684 val = REG_RD(sc, BCE_TBDR_CONFIG); 3685 val &= ~BCE_TBDR_CONFIG_PAGE_SIZE; 3686 val |= (BCM_PAGE_BITS - 8) << 24 | 0x40; 3687 REG_WR(sc, BCE_TBDR_CONFIG, val); 3688 3689 /* Set the perfect match control register to default. */ 3690 REG_WR_IND(sc, BCE_RXP_PM_CTRL, 0); 3691 3692 return 0; 3693 } 3694 3695 /****************************************************************************/ 3696 /* Initialize the controller in preparation to send/receive traffic. */ 3697 /* */ 3698 /* Returns: */ 3699 /* 0 for success, positive value for failure. */ 3700 /****************************************************************************/ 3701 static int 3702 bce_blockinit(struct bce_softc *sc) 3703 { 3704 uint32_t reg, val; 3705 int i; 3706 3707 /* Load the hardware default MAC address. */ 3708 bce_set_mac_addr(sc); 3709 3710 /* Set the Ethernet backoff seed value */ 3711 val = sc->eaddr[0] + (sc->eaddr[1] << 8) + (sc->eaddr[2] << 16) + 3712 sc->eaddr[3] + (sc->eaddr[4] << 8) + (sc->eaddr[5] << 16); 3713 REG_WR(sc, BCE_EMAC_BACKOFF_SEED, val); 3714 3715 sc->rx_mode = BCE_EMAC_RX_MODE_SORT_MODE; 3716 3717 /* Set up link change interrupt generation. */ 3718 REG_WR(sc, BCE_EMAC_ATTENTION_ENA, BCE_EMAC_ATTENTION_ENA_LINK); 3719 3720 /* Program the physical address of the status block. */ 3721 REG_WR(sc, BCE_HC_STATUS_ADDR_L, BCE_ADDR_LO(sc->status_block_paddr)); 3722 REG_WR(sc, BCE_HC_STATUS_ADDR_H, BCE_ADDR_HI(sc->status_block_paddr)); 3723 3724 /* Program the physical address of the statistics block. */ 3725 REG_WR(sc, BCE_HC_STATISTICS_ADDR_L, 3726 BCE_ADDR_LO(sc->stats_block_paddr)); 3727 REG_WR(sc, BCE_HC_STATISTICS_ADDR_H, 3728 BCE_ADDR_HI(sc->stats_block_paddr)); 3729 3730 /* Program various host coalescing parameters. */ 3731 REG_WR(sc, BCE_HC_TX_QUICK_CONS_TRIP, 3732 (sc->bce_tx_quick_cons_trip_int << 16) | 3733 sc->bce_tx_quick_cons_trip); 3734 REG_WR(sc, BCE_HC_RX_QUICK_CONS_TRIP, 3735 (sc->bce_rx_quick_cons_trip_int << 16) | 3736 sc->bce_rx_quick_cons_trip); 3737 REG_WR(sc, BCE_HC_COMP_PROD_TRIP, 3738 (sc->bce_comp_prod_trip_int << 16) | sc->bce_comp_prod_trip); 3739 REG_WR(sc, BCE_HC_TX_TICKS, 3740 (sc->bce_tx_ticks_int << 16) | sc->bce_tx_ticks); 3741 REG_WR(sc, BCE_HC_RX_TICKS, 3742 (sc->bce_rx_ticks_int << 16) | sc->bce_rx_ticks); 3743 REG_WR(sc, BCE_HC_COM_TICKS, 3744 (sc->bce_com_ticks_int << 16) | sc->bce_com_ticks); 3745 REG_WR(sc, BCE_HC_CMD_TICKS, 3746 (sc->bce_cmd_ticks_int << 16) | sc->bce_cmd_ticks); 3747 REG_WR(sc, BCE_HC_STATS_TICKS, (sc->bce_stats_ticks & 0xffff00)); 3748 REG_WR(sc, BCE_HC_STAT_COLLECT_TICKS, 0xbb8); /* 3ms */ 3749 3750 if (sc->bce_irq_type == PCI_INTR_TYPE_MSIX) 3751 REG_WR(sc, BCE_HC_MSIX_BIT_VECTOR, BCE_HC_MSIX_BIT_VECTOR_VAL); 3752 3753 val = BCE_HC_CONFIG_TX_TMR_MODE | BCE_HC_CONFIG_COLLECT_STATS; 3754 if ((sc->bce_flags & BCE_ONESHOT_MSI_FLAG) || 3755 sc->bce_irq_type == PCI_INTR_TYPE_MSIX) { 3756 if (bootverbose) { 3757 if (sc->bce_irq_type == PCI_INTR_TYPE_MSIX) { 3758 if_printf(&sc->arpcom.ac_if, 3759 "using MSI-X\n"); 3760 } else { 3761 if_printf(&sc->arpcom.ac_if, 3762 "using oneshot MSI\n"); 3763 } 3764 } 3765 val |= BCE_HC_CONFIG_ONE_SHOT | BCE_HC_CONFIG_USE_INT_PARAM; 3766 if (sc->bce_irq_type == PCI_INTR_TYPE_MSIX) 3767 val |= BCE_HC_CONFIG_SB_ADDR_INC_128B; 3768 } 3769 REG_WR(sc, BCE_HC_CONFIG, val); 3770 3771 for (i = 1; i < sc->rx_ring_cnt; ++i) { 3772 uint32_t base; 3773 3774 base = ((i - 1) * BCE_HC_SB_CONFIG_SIZE) + BCE_HC_SB_CONFIG_1; 3775 KKASSERT(base <= BCE_HC_SB_CONFIG_8); 3776 3777 REG_WR(sc, base, 3778 BCE_HC_SB_CONFIG_1_TX_TMR_MODE | 3779 /* BCE_HC_SB_CONFIG_1_RX_TMR_MODE | */ 3780 BCE_HC_SB_CONFIG_1_ONE_SHOT); 3781 3782 REG_WR(sc, base + BCE_HC_TX_QUICK_CONS_TRIP_OFF, 3783 (sc->bce_tx_quick_cons_trip_int << 16) | 3784 sc->bce_tx_quick_cons_trip); 3785 REG_WR(sc, base + BCE_HC_RX_QUICK_CONS_TRIP_OFF, 3786 (sc->bce_rx_quick_cons_trip_int << 16) | 3787 sc->bce_rx_quick_cons_trip); 3788 REG_WR(sc, base + BCE_HC_TX_TICKS_OFF, 3789 (sc->bce_tx_ticks_int << 16) | sc->bce_tx_ticks); 3790 REG_WR(sc, base + BCE_HC_RX_TICKS_OFF, 3791 (sc->bce_rx_ticks_int << 16) | sc->bce_rx_ticks); 3792 } 3793 3794 /* Clear the internal statistics counters. */ 3795 REG_WR(sc, BCE_HC_COMMAND, BCE_HC_COMMAND_CLR_STAT_NOW); 3796 3797 /* Verify that bootcode is running. */ 3798 reg = bce_shmem_rd(sc, BCE_DEV_INFO_SIGNATURE); 3799 3800 if ((reg & BCE_DEV_INFO_SIGNATURE_MAGIC_MASK) != 3801 BCE_DEV_INFO_SIGNATURE_MAGIC) { 3802 if_printf(&sc->arpcom.ac_if, 3803 "Bootcode not running! Found: 0x%08X, " 3804 "Expected: 08%08X\n", 3805 reg & BCE_DEV_INFO_SIGNATURE_MAGIC_MASK, 3806 BCE_DEV_INFO_SIGNATURE_MAGIC); 3807 return ENODEV; 3808 } 3809 3810 /* Enable DMA */ 3811 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 3812 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 3813 val = REG_RD(sc, BCE_MISC_NEW_CORE_CTL); 3814 val |= BCE_MISC_NEW_CORE_CTL_DMA_ENABLE; 3815 REG_WR(sc, BCE_MISC_NEW_CORE_CTL, val); 3816 } 3817 3818 /* Allow bootcode to apply any additional fixes before enabling MAC. */ 3819 bce_fw_sync(sc, BCE_DRV_MSG_DATA_WAIT2 | BCE_DRV_MSG_CODE_RESET); 3820 3821 /* Enable link state change interrupt generation. */ 3822 REG_WR(sc, BCE_HC_ATTN_BITS_ENABLE, STATUS_ATTN_BITS_LINK_STATE); 3823 3824 /* Enable the RXP. */ 3825 bce_start_rxp_cpu(sc); 3826 3827 /* Disable management frames (NC-SI) from flowing to the MCP. */ 3828 if (sc->bce_flags & BCE_MFW_ENABLE_FLAG) { 3829 val = REG_RD(sc, BCE_RPM_MGMT_PKT_CTRL) & 3830 ~BCE_RPM_MGMT_PKT_CTRL_MGMT_EN; 3831 REG_WR(sc, BCE_RPM_MGMT_PKT_CTRL, val); 3832 } 3833 3834 /* Enable all remaining blocks in the MAC. */ 3835 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 3836 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 3837 REG_WR(sc, BCE_MISC_ENABLE_SET_BITS, 3838 BCE_MISC_ENABLE_DEFAULT_XI); 3839 } else { 3840 REG_WR(sc, BCE_MISC_ENABLE_SET_BITS, BCE_MISC_ENABLE_DEFAULT); 3841 } 3842 REG_RD(sc, BCE_MISC_ENABLE_SET_BITS); 3843 DELAY(20); 3844 3845 /* Save the current host coalescing block settings. */ 3846 sc->hc_command = REG_RD(sc, BCE_HC_COMMAND); 3847 3848 return 0; 3849 } 3850 3851 /****************************************************************************/ 3852 /* Encapsulate an mbuf cluster into the rx_bd chain. */ 3853 /* */ 3854 /* The NetXtreme II can support Jumbo frames by using multiple rx_bd's. */ 3855 /* This routine will map an mbuf cluster into 1 or more rx_bd's as */ 3856 /* necessary. */ 3857 /* */ 3858 /* Returns: */ 3859 /* 0 for success, positive value for failure. */ 3860 /****************************************************************************/ 3861 static int 3862 bce_newbuf_std(struct bce_rx_ring *rxr, uint16_t *prod, uint16_t chain_prod, 3863 uint32_t *prod_bseq, int init) 3864 { 3865 struct bce_rx_buf *rx_buf; 3866 bus_dmamap_t map; 3867 bus_dma_segment_t seg; 3868 struct mbuf *m_new; 3869 int error, nseg; 3870 3871 /* This is a new mbuf allocation. */ 3872 m_new = m_getcl(init ? M_WAITOK : M_NOWAIT, MT_DATA, M_PKTHDR); 3873 if (m_new == NULL) 3874 return ENOBUFS; 3875 3876 m_new->m_len = m_new->m_pkthdr.len = MCLBYTES; 3877 3878 /* Map the mbuf cluster into device memory. */ 3879 error = bus_dmamap_load_mbuf_segment(rxr->rx_mbuf_tag, 3880 rxr->rx_mbuf_tmpmap, m_new, &seg, 1, &nseg, BUS_DMA_NOWAIT); 3881 if (error) { 3882 m_freem(m_new); 3883 if (init) { 3884 if_printf(&rxr->sc->arpcom.ac_if, 3885 "Error mapping mbuf into RX chain!\n"); 3886 } 3887 return error; 3888 } 3889 3890 rx_buf = &rxr->rx_bufs[chain_prod]; 3891 if (rx_buf->rx_mbuf_ptr != NULL) 3892 bus_dmamap_unload(rxr->rx_mbuf_tag, rx_buf->rx_mbuf_map); 3893 3894 map = rx_buf->rx_mbuf_map; 3895 rx_buf->rx_mbuf_map = rxr->rx_mbuf_tmpmap; 3896 rxr->rx_mbuf_tmpmap = map; 3897 3898 /* Save the mbuf and update our counter. */ 3899 rx_buf->rx_mbuf_ptr = m_new; 3900 rx_buf->rx_mbuf_paddr = seg.ds_addr; 3901 rxr->free_rx_bd--; 3902 3903 bce_setup_rxdesc_std(rxr, chain_prod, prod_bseq); 3904 3905 return 0; 3906 } 3907 3908 static void 3909 bce_setup_rxdesc_std(struct bce_rx_ring *rxr, uint16_t chain_prod, 3910 uint32_t *prod_bseq) 3911 { 3912 const struct bce_rx_buf *rx_buf; 3913 struct rx_bd *rxbd; 3914 bus_addr_t paddr; 3915 int len; 3916 3917 rx_buf = &rxr->rx_bufs[chain_prod]; 3918 paddr = rx_buf->rx_mbuf_paddr; 3919 len = rx_buf->rx_mbuf_ptr->m_len; 3920 3921 /* Setup the rx_bd for the first segment. */ 3922 rxbd = &rxr->rx_bd_chain[RX_PAGE(chain_prod)][RX_IDX(chain_prod)]; 3923 3924 rxbd->rx_bd_haddr_lo = htole32(BCE_ADDR_LO(paddr)); 3925 rxbd->rx_bd_haddr_hi = htole32(BCE_ADDR_HI(paddr)); 3926 rxbd->rx_bd_len = htole32(len); 3927 rxbd->rx_bd_flags = htole32(RX_BD_FLAGS_START); 3928 *prod_bseq += len; 3929 3930 rxbd->rx_bd_flags |= htole32(RX_BD_FLAGS_END); 3931 } 3932 3933 /****************************************************************************/ 3934 /* Initialize the TX context memory. */ 3935 /* */ 3936 /* Returns: */ 3937 /* Nothing */ 3938 /****************************************************************************/ 3939 static void 3940 bce_init_tx_context(struct bce_tx_ring *txr) 3941 { 3942 uint32_t val; 3943 3944 /* Initialize the context ID for an L2 TX chain. */ 3945 if (BCE_CHIP_NUM(txr->sc) == BCE_CHIP_NUM_5709 || 3946 BCE_CHIP_NUM(txr->sc) == BCE_CHIP_NUM_5716) { 3947 /* Set the CID type to support an L2 connection. */ 3948 val = BCE_L2CTX_TX_TYPE_TYPE_L2 | BCE_L2CTX_TX_TYPE_SIZE_L2; 3949 CTX_WR(txr->sc, GET_CID_ADDR(txr->tx_cid), 3950 BCE_L2CTX_TX_TYPE_XI, val); 3951 val = BCE_L2CTX_TX_CMD_TYPE_TYPE_L2 | (8 << 16); 3952 CTX_WR(txr->sc, GET_CID_ADDR(txr->tx_cid), 3953 BCE_L2CTX_TX_CMD_TYPE_XI, val); 3954 3955 /* Point the hardware to the first page in the chain. */ 3956 val = BCE_ADDR_HI(txr->tx_bd_chain_paddr[0]); 3957 CTX_WR(txr->sc, GET_CID_ADDR(txr->tx_cid), 3958 BCE_L2CTX_TX_TBDR_BHADDR_HI_XI, val); 3959 val = BCE_ADDR_LO(txr->tx_bd_chain_paddr[0]); 3960 CTX_WR(txr->sc, GET_CID_ADDR(txr->tx_cid), 3961 BCE_L2CTX_TX_TBDR_BHADDR_LO_XI, val); 3962 } else { 3963 /* Set the CID type to support an L2 connection. */ 3964 val = BCE_L2CTX_TX_TYPE_TYPE_L2 | BCE_L2CTX_TX_TYPE_SIZE_L2; 3965 CTX_WR(txr->sc, GET_CID_ADDR(txr->tx_cid), 3966 BCE_L2CTX_TX_TYPE, val); 3967 val = BCE_L2CTX_TX_CMD_TYPE_TYPE_L2 | (8 << 16); 3968 CTX_WR(txr->sc, GET_CID_ADDR(txr->tx_cid), 3969 BCE_L2CTX_TX_CMD_TYPE, val); 3970 3971 /* Point the hardware to the first page in the chain. */ 3972 val = BCE_ADDR_HI(txr->tx_bd_chain_paddr[0]); 3973 CTX_WR(txr->sc, GET_CID_ADDR(txr->tx_cid), 3974 BCE_L2CTX_TX_TBDR_BHADDR_HI, val); 3975 val = BCE_ADDR_LO(txr->tx_bd_chain_paddr[0]); 3976 CTX_WR(txr->sc, GET_CID_ADDR(txr->tx_cid), 3977 BCE_L2CTX_TX_TBDR_BHADDR_LO, val); 3978 } 3979 } 3980 3981 /****************************************************************************/ 3982 /* Allocate memory and initialize the TX data structures. */ 3983 /* */ 3984 /* Returns: */ 3985 /* 0 for success, positive value for failure. */ 3986 /****************************************************************************/ 3987 static int 3988 bce_init_tx_chain(struct bce_tx_ring *txr) 3989 { 3990 struct tx_bd *txbd; 3991 int i, rc = 0; 3992 3993 /* Set the initial TX producer/consumer indices. */ 3994 txr->tx_prod = 0; 3995 txr->tx_cons = 0; 3996 txr->tx_prod_bseq = 0; 3997 txr->used_tx_bd = 0; 3998 txr->max_tx_bd = USABLE_TX_BD(txr); 3999 4000 /* 4001 * The NetXtreme II supports a linked-list structre called 4002 * a Buffer Descriptor Chain (or BD chain). A BD chain 4003 * consists of a series of 1 or more chain pages, each of which 4004 * consists of a fixed number of BD entries. 4005 * The last BD entry on each page is a pointer to the next page 4006 * in the chain, and the last pointer in the BD chain 4007 * points back to the beginning of the chain. 4008 */ 4009 4010 /* Set the TX next pointer chain entries. */ 4011 for (i = 0; i < txr->tx_pages; i++) { 4012 int j; 4013 4014 txbd = &txr->tx_bd_chain[i][USABLE_TX_BD_PER_PAGE]; 4015 4016 /* Check if we've reached the last page. */ 4017 if (i == (txr->tx_pages - 1)) 4018 j = 0; 4019 else 4020 j = i + 1; 4021 4022 txbd->tx_bd_haddr_hi = 4023 htole32(BCE_ADDR_HI(txr->tx_bd_chain_paddr[j])); 4024 txbd->tx_bd_haddr_lo = 4025 htole32(BCE_ADDR_LO(txr->tx_bd_chain_paddr[j])); 4026 } 4027 bce_init_tx_context(txr); 4028 4029 return(rc); 4030 } 4031 4032 /****************************************************************************/ 4033 /* Free memory and clear the TX data structures. */ 4034 /* */ 4035 /* Returns: */ 4036 /* Nothing. */ 4037 /****************************************************************************/ 4038 static void 4039 bce_free_tx_chain(struct bce_tx_ring *txr) 4040 { 4041 int i; 4042 4043 /* Unmap, unload, and free any mbufs still in the TX mbuf chain. */ 4044 for (i = 0; i < TOTAL_TX_BD(txr); i++) { 4045 struct bce_tx_buf *tx_buf = &txr->tx_bufs[i]; 4046 4047 if (tx_buf->tx_mbuf_ptr != NULL) { 4048 bus_dmamap_unload(txr->tx_mbuf_tag, 4049 tx_buf->tx_mbuf_map); 4050 m_freem(tx_buf->tx_mbuf_ptr); 4051 tx_buf->tx_mbuf_ptr = NULL; 4052 } 4053 } 4054 4055 /* Clear each TX chain page. */ 4056 for (i = 0; i < txr->tx_pages; i++) 4057 bzero(txr->tx_bd_chain[i], BCE_TX_CHAIN_PAGE_SZ); 4058 txr->used_tx_bd = 0; 4059 } 4060 4061 /****************************************************************************/ 4062 /* Initialize the RX context memory. */ 4063 /* */ 4064 /* Returns: */ 4065 /* Nothing */ 4066 /****************************************************************************/ 4067 static void 4068 bce_init_rx_context(struct bce_rx_ring *rxr) 4069 { 4070 uint32_t val; 4071 4072 /* Initialize the context ID for an L2 RX chain. */ 4073 val = BCE_L2CTX_RX_CTX_TYPE_CTX_BD_CHN_TYPE_VALUE | 4074 BCE_L2CTX_RX_CTX_TYPE_SIZE_L2 | (0x02 << 8); 4075 4076 /* 4077 * Set the level for generating pause frames 4078 * when the number of available rx_bd's gets 4079 * too low (the low watermark) and the level 4080 * when pause frames can be stopped (the high 4081 * watermark). 4082 */ 4083 if (BCE_CHIP_NUM(rxr->sc) == BCE_CHIP_NUM_5709 || 4084 BCE_CHIP_NUM(rxr->sc) == BCE_CHIP_NUM_5716) { 4085 uint32_t lo_water, hi_water; 4086 4087 lo_water = BCE_L2CTX_RX_LO_WATER_MARK_DEFAULT; 4088 hi_water = USABLE_RX_BD(rxr) / 4; 4089 4090 lo_water /= BCE_L2CTX_RX_LO_WATER_MARK_SCALE; 4091 hi_water /= BCE_L2CTX_RX_HI_WATER_MARK_SCALE; 4092 4093 if (hi_water > 0xf) 4094 hi_water = 0xf; 4095 else if (hi_water == 0) 4096 lo_water = 0; 4097 val |= lo_water | 4098 (hi_water << BCE_L2CTX_RX_HI_WATER_MARK_SHIFT); 4099 } 4100 4101 CTX_WR(rxr->sc, GET_CID_ADDR(rxr->rx_cid), 4102 BCE_L2CTX_RX_CTX_TYPE, val); 4103 4104 /* Setup the MQ BIN mapping for l2_ctx_host_bseq. */ 4105 if (BCE_CHIP_NUM(rxr->sc) == BCE_CHIP_NUM_5709 || 4106 BCE_CHIP_NUM(rxr->sc) == BCE_CHIP_NUM_5716) { 4107 val = REG_RD(rxr->sc, BCE_MQ_MAP_L2_5); 4108 REG_WR(rxr->sc, BCE_MQ_MAP_L2_5, val | BCE_MQ_MAP_L2_5_ARM); 4109 } 4110 4111 /* Point the hardware to the first page in the chain. */ 4112 val = BCE_ADDR_HI(rxr->rx_bd_chain_paddr[0]); 4113 CTX_WR(rxr->sc, GET_CID_ADDR(rxr->rx_cid), 4114 BCE_L2CTX_RX_NX_BDHADDR_HI, val); 4115 val = BCE_ADDR_LO(rxr->rx_bd_chain_paddr[0]); 4116 CTX_WR(rxr->sc, GET_CID_ADDR(rxr->rx_cid), 4117 BCE_L2CTX_RX_NX_BDHADDR_LO, val); 4118 } 4119 4120 /****************************************************************************/ 4121 /* Allocate memory and initialize the RX data structures. */ 4122 /* */ 4123 /* Returns: */ 4124 /* 0 for success, positive value for failure. */ 4125 /****************************************************************************/ 4126 static int 4127 bce_init_rx_chain(struct bce_rx_ring *rxr) 4128 { 4129 struct rx_bd *rxbd; 4130 int i, rc = 0; 4131 uint16_t prod, chain_prod; 4132 uint32_t prod_bseq; 4133 4134 /* Initialize the RX producer and consumer indices. */ 4135 rxr->rx_prod = 0; 4136 rxr->rx_cons = 0; 4137 rxr->rx_prod_bseq = 0; 4138 rxr->free_rx_bd = USABLE_RX_BD(rxr); 4139 rxr->max_rx_bd = USABLE_RX_BD(rxr); 4140 4141 /* Clear cache status index */ 4142 rxr->last_status_idx = 0; 4143 4144 /* Initialize the RX next pointer chain entries. */ 4145 for (i = 0; i < rxr->rx_pages; i++) { 4146 int j; 4147 4148 rxbd = &rxr->rx_bd_chain[i][USABLE_RX_BD_PER_PAGE]; 4149 4150 /* Check if we've reached the last page. */ 4151 if (i == (rxr->rx_pages - 1)) 4152 j = 0; 4153 else 4154 j = i + 1; 4155 4156 /* Setup the chain page pointers. */ 4157 rxbd->rx_bd_haddr_hi = 4158 htole32(BCE_ADDR_HI(rxr->rx_bd_chain_paddr[j])); 4159 rxbd->rx_bd_haddr_lo = 4160 htole32(BCE_ADDR_LO(rxr->rx_bd_chain_paddr[j])); 4161 } 4162 4163 /* Allocate mbuf clusters for the rx_bd chain. */ 4164 prod = prod_bseq = 0; 4165 while (prod < TOTAL_RX_BD(rxr)) { 4166 chain_prod = RX_CHAIN_IDX(rxr, prod); 4167 if (bce_newbuf_std(rxr, &prod, chain_prod, &prod_bseq, 1)) { 4168 if_printf(&rxr->sc->arpcom.ac_if, 4169 "Error filling RX chain: rx_bd[0x%04X]!\n", 4170 chain_prod); 4171 rc = ENOBUFS; 4172 break; 4173 } 4174 prod = NEXT_RX_BD(prod); 4175 } 4176 4177 /* Save the RX chain producer index. */ 4178 rxr->rx_prod = prod; 4179 rxr->rx_prod_bseq = prod_bseq; 4180 4181 /* Tell the chip about the waiting rx_bd's. */ 4182 REG_WR16(rxr->sc, MB_GET_CID_ADDR(rxr->rx_cid) + BCE_L2MQ_RX_HOST_BDIDX, 4183 rxr->rx_prod); 4184 REG_WR(rxr->sc, MB_GET_CID_ADDR(rxr->rx_cid) + BCE_L2MQ_RX_HOST_BSEQ, 4185 rxr->rx_prod_bseq); 4186 4187 bce_init_rx_context(rxr); 4188 4189 return(rc); 4190 } 4191 4192 /****************************************************************************/ 4193 /* Free memory and clear the RX data structures. */ 4194 /* */ 4195 /* Returns: */ 4196 /* Nothing. */ 4197 /****************************************************************************/ 4198 static void 4199 bce_free_rx_chain(struct bce_rx_ring *rxr) 4200 { 4201 int i; 4202 4203 /* Free any mbufs still in the RX mbuf chain. */ 4204 for (i = 0; i < TOTAL_RX_BD(rxr); i++) { 4205 struct bce_rx_buf *rx_buf = &rxr->rx_bufs[i]; 4206 4207 if (rx_buf->rx_mbuf_ptr != NULL) { 4208 bus_dmamap_unload(rxr->rx_mbuf_tag, 4209 rx_buf->rx_mbuf_map); 4210 m_freem(rx_buf->rx_mbuf_ptr); 4211 rx_buf->rx_mbuf_ptr = NULL; 4212 } 4213 } 4214 4215 /* Clear each RX chain page. */ 4216 for (i = 0; i < rxr->rx_pages; i++) 4217 bzero(rxr->rx_bd_chain[i], BCE_RX_CHAIN_PAGE_SZ); 4218 } 4219 4220 /****************************************************************************/ 4221 /* Set media options. */ 4222 /* */ 4223 /* Returns: */ 4224 /* 0 for success, positive value for failure. */ 4225 /****************************************************************************/ 4226 static int 4227 bce_ifmedia_upd(struct ifnet *ifp) 4228 { 4229 struct bce_softc *sc = ifp->if_softc; 4230 struct mii_data *mii = device_get_softc(sc->bce_miibus); 4231 int error = 0; 4232 4233 /* 4234 * 'mii' will be NULL, when this function is called on following 4235 * code path: bce_attach() -> bce_mgmt_init() 4236 */ 4237 if (mii != NULL) { 4238 /* Make sure the MII bus has been enumerated. */ 4239 sc->bce_link = 0; 4240 if (mii->mii_instance) { 4241 struct mii_softc *miisc; 4242 4243 LIST_FOREACH(miisc, &mii->mii_phys, mii_list) 4244 mii_phy_reset(miisc); 4245 } 4246 error = mii_mediachg(mii); 4247 } 4248 return error; 4249 } 4250 4251 /****************************************************************************/ 4252 /* Reports current media status. */ 4253 /* */ 4254 /* Returns: */ 4255 /* Nothing. */ 4256 /****************************************************************************/ 4257 static void 4258 bce_ifmedia_sts(struct ifnet *ifp, struct ifmediareq *ifmr) 4259 { 4260 struct bce_softc *sc = ifp->if_softc; 4261 struct mii_data *mii = device_get_softc(sc->bce_miibus); 4262 4263 mii_pollstat(mii); 4264 ifmr->ifm_active = mii->mii_media_active; 4265 ifmr->ifm_status = mii->mii_media_status; 4266 } 4267 4268 /****************************************************************************/ 4269 /* Handles PHY generated interrupt events. */ 4270 /* */ 4271 /* Returns: */ 4272 /* Nothing. */ 4273 /****************************************************************************/ 4274 static void 4275 bce_phy_intr(struct bce_softc *sc) 4276 { 4277 uint32_t new_link_state, old_link_state; 4278 struct ifnet *ifp = &sc->arpcom.ac_if; 4279 4280 ASSERT_SERIALIZED(&sc->main_serialize); 4281 4282 new_link_state = sc->status_block->status_attn_bits & 4283 STATUS_ATTN_BITS_LINK_STATE; 4284 old_link_state = sc->status_block->status_attn_bits_ack & 4285 STATUS_ATTN_BITS_LINK_STATE; 4286 4287 /* Handle any changes if the link state has changed. */ 4288 if (new_link_state != old_link_state) { /* XXX redundant? */ 4289 /* Update the status_attn_bits_ack field in the status block. */ 4290 if (new_link_state) { 4291 REG_WR(sc, BCE_PCICFG_STATUS_BIT_SET_CMD, 4292 STATUS_ATTN_BITS_LINK_STATE); 4293 if (bootverbose) 4294 if_printf(ifp, "Link is now UP.\n"); 4295 } else { 4296 REG_WR(sc, BCE_PCICFG_STATUS_BIT_CLEAR_CMD, 4297 STATUS_ATTN_BITS_LINK_STATE); 4298 if (bootverbose) 4299 if_printf(ifp, "Link is now DOWN.\n"); 4300 } 4301 4302 /* 4303 * Assume link is down and allow tick routine to 4304 * update the state based on the actual media state. 4305 */ 4306 sc->bce_link = 0; 4307 callout_stop(&sc->bce_tick_callout); 4308 bce_tick_serialized(sc); 4309 } 4310 4311 /* Acknowledge the link change interrupt. */ 4312 REG_WR(sc, BCE_EMAC_STATUS, BCE_EMAC_STATUS_LINK_CHANGE); 4313 } 4314 4315 /****************************************************************************/ 4316 /* Reads the receive consumer value from the status block (skipping over */ 4317 /* chain page pointer if necessary). */ 4318 /* */ 4319 /* Returns: */ 4320 /* hw_cons */ 4321 /****************************************************************************/ 4322 static __inline uint16_t 4323 bce_get_hw_rx_cons(struct bce_rx_ring *rxr) 4324 { 4325 uint16_t hw_cons = *rxr->rx_hw_cons; 4326 4327 if ((hw_cons & USABLE_RX_BD_PER_PAGE) == USABLE_RX_BD_PER_PAGE) 4328 hw_cons++; 4329 return hw_cons; 4330 } 4331 4332 /****************************************************************************/ 4333 /* Handles received frame interrupt events. */ 4334 /* */ 4335 /* Returns: */ 4336 /* Nothing. */ 4337 /****************************************************************************/ 4338 static void 4339 bce_rx_intr(struct bce_rx_ring *rxr, int count, uint16_t hw_cons) 4340 { 4341 struct ifnet *ifp = &rxr->sc->arpcom.ac_if; 4342 uint16_t sw_cons, sw_chain_cons, sw_prod, sw_chain_prod; 4343 uint32_t sw_prod_bseq; 4344 int cpuid = mycpuid; 4345 4346 ASSERT_SERIALIZED(&rxr->rx_serialize); 4347 4348 /* Get working copies of the driver's view of the RX indices. */ 4349 sw_cons = rxr->rx_cons; 4350 sw_prod = rxr->rx_prod; 4351 sw_prod_bseq = rxr->rx_prod_bseq; 4352 4353 /* Scan through the receive chain as long as there is work to do. */ 4354 while (sw_cons != hw_cons) { 4355 struct pktinfo pi0, *pi = NULL; 4356 struct bce_rx_buf *rx_buf; 4357 struct mbuf *m = NULL; 4358 struct l2_fhdr *l2fhdr = NULL; 4359 unsigned int len; 4360 uint32_t status = 0; 4361 4362 #ifdef IFPOLL_ENABLE 4363 if (count >= 0 && count-- == 0) 4364 break; 4365 #endif 4366 4367 /* 4368 * Convert the producer/consumer indices 4369 * to an actual rx_bd index. 4370 */ 4371 sw_chain_cons = RX_CHAIN_IDX(rxr, sw_cons); 4372 sw_chain_prod = RX_CHAIN_IDX(rxr, sw_prod); 4373 rx_buf = &rxr->rx_bufs[sw_chain_cons]; 4374 4375 rxr->free_rx_bd++; 4376 4377 /* The mbuf is stored with the last rx_bd entry of a packet. */ 4378 if (rx_buf->rx_mbuf_ptr != NULL) { 4379 if (sw_chain_cons != sw_chain_prod) { 4380 if_printf(ifp, "RX cons(%d) != prod(%d), " 4381 "drop!\n", sw_chain_cons, sw_chain_prod); 4382 IFNET_STAT_INC(ifp, ierrors, 1); 4383 4384 bce_setup_rxdesc_std(rxr, sw_chain_cons, 4385 &sw_prod_bseq); 4386 m = NULL; 4387 goto bce_rx_int_next_rx; 4388 } 4389 4390 /* Unmap the mbuf from DMA space. */ 4391 bus_dmamap_sync(rxr->rx_mbuf_tag, rx_buf->rx_mbuf_map, 4392 BUS_DMASYNC_POSTREAD); 4393 4394 /* Save the mbuf from the driver's chain. */ 4395 m = rx_buf->rx_mbuf_ptr; 4396 4397 /* 4398 * Frames received on the NetXteme II are prepended 4399 * with an l2_fhdr structure which provides status 4400 * information about the received frame (including 4401 * VLAN tags and checksum info). The frames are also 4402 * automatically adjusted to align the IP header 4403 * (i.e. two null bytes are inserted before the 4404 * Ethernet header). As a result the data DMA'd by 4405 * the controller into the mbuf is as follows: 4406 * 4407 * +---------+-----+---------------------+-----+ 4408 * | l2_fhdr | pad | packet data | FCS | 4409 * +---------+-----+---------------------+-----+ 4410 * 4411 * The l2_fhdr needs to be checked and skipped and the 4412 * FCS needs to be stripped before sending the packet 4413 * up the stack. 4414 */ 4415 l2fhdr = mtod(m, struct l2_fhdr *); 4416 4417 len = l2fhdr->l2_fhdr_pkt_len; 4418 status = l2fhdr->l2_fhdr_status; 4419 4420 len -= ETHER_CRC_LEN; 4421 4422 /* Check the received frame for errors. */ 4423 if (status & (L2_FHDR_ERRORS_BAD_CRC | 4424 L2_FHDR_ERRORS_PHY_DECODE | 4425 L2_FHDR_ERRORS_ALIGNMENT | 4426 L2_FHDR_ERRORS_TOO_SHORT | 4427 L2_FHDR_ERRORS_GIANT_FRAME)) { 4428 IFNET_STAT_INC(ifp, ierrors, 1); 4429 4430 /* Reuse the mbuf for a new frame. */ 4431 bce_setup_rxdesc_std(rxr, sw_chain_prod, 4432 &sw_prod_bseq); 4433 m = NULL; 4434 goto bce_rx_int_next_rx; 4435 } 4436 4437 /* 4438 * Get a new mbuf for the rx_bd. If no new 4439 * mbufs are available then reuse the current mbuf, 4440 * log an ierror on the interface, and generate 4441 * an error in the system log. 4442 */ 4443 if (bce_newbuf_std(rxr, &sw_prod, sw_chain_prod, 4444 &sw_prod_bseq, 0)) { 4445 IFNET_STAT_INC(ifp, ierrors, 1); 4446 4447 /* Try and reuse the exisitng mbuf. */ 4448 bce_setup_rxdesc_std(rxr, sw_chain_prod, 4449 &sw_prod_bseq); 4450 m = NULL; 4451 goto bce_rx_int_next_rx; 4452 } 4453 4454 /* 4455 * Skip over the l2_fhdr when passing 4456 * the data up the stack. 4457 */ 4458 m_adj(m, sizeof(struct l2_fhdr) + ETHER_ALIGN); 4459 4460 m->m_pkthdr.len = m->m_len = len; 4461 m->m_pkthdr.rcvif = ifp; 4462 4463 /* Validate the checksum if offload enabled. */ 4464 if (ifp->if_capenable & IFCAP_RXCSUM) { 4465 /* Check for an IP datagram. */ 4466 if (status & L2_FHDR_STATUS_IP_DATAGRAM) { 4467 m->m_pkthdr.csum_flags |= 4468 CSUM_IP_CHECKED; 4469 4470 /* Check if the IP checksum is valid. */ 4471 if ((l2fhdr->l2_fhdr_ip_xsum ^ 4472 0xffff) == 0) { 4473 m->m_pkthdr.csum_flags |= 4474 CSUM_IP_VALID; 4475 } 4476 } 4477 4478 /* Check for a valid TCP/UDP frame. */ 4479 if (status & (L2_FHDR_STATUS_TCP_SEGMENT | 4480 L2_FHDR_STATUS_UDP_DATAGRAM)) { 4481 4482 /* Check for a good TCP/UDP checksum. */ 4483 if ((status & 4484 (L2_FHDR_ERRORS_TCP_XSUM | 4485 L2_FHDR_ERRORS_UDP_XSUM)) == 0) { 4486 m->m_pkthdr.csum_data = 4487 l2fhdr->l2_fhdr_tcp_udp_xsum; 4488 m->m_pkthdr.csum_flags |= 4489 CSUM_DATA_VALID | 4490 CSUM_PSEUDO_HDR; 4491 } 4492 } 4493 } 4494 if (ifp->if_capenable & IFCAP_RSS) { 4495 pi = bce_rss_pktinfo(&pi0, status, l2fhdr); 4496 if (pi != NULL && 4497 (status & L2_FHDR_STATUS_RSS_HASH)) { 4498 m->m_flags |= M_HASH; 4499 m->m_pkthdr.hash = 4500 toeplitz_hash(l2fhdr->l2_fhdr_hash); 4501 } 4502 } 4503 4504 IFNET_STAT_INC(ifp, ipackets, 1); 4505 bce_rx_int_next_rx: 4506 sw_prod = NEXT_RX_BD(sw_prod); 4507 } 4508 4509 sw_cons = NEXT_RX_BD(sw_cons); 4510 4511 /* If we have a packet, pass it up the stack */ 4512 if (m) { 4513 if (status & L2_FHDR_STATUS_L2_VLAN_TAG) { 4514 m->m_flags |= M_VLANTAG; 4515 m->m_pkthdr.ether_vlantag = 4516 l2fhdr->l2_fhdr_vlan_tag; 4517 } 4518 ifp->if_input(ifp, m, pi, cpuid); 4519 #ifdef BCE_RSS_DEBUG 4520 rxr->rx_pkts++; 4521 #endif 4522 } 4523 } 4524 4525 rxr->rx_cons = sw_cons; 4526 rxr->rx_prod = sw_prod; 4527 rxr->rx_prod_bseq = sw_prod_bseq; 4528 4529 REG_WR16(rxr->sc, MB_GET_CID_ADDR(rxr->rx_cid) + BCE_L2MQ_RX_HOST_BDIDX, 4530 rxr->rx_prod); 4531 REG_WR(rxr->sc, MB_GET_CID_ADDR(rxr->rx_cid) + BCE_L2MQ_RX_HOST_BSEQ, 4532 rxr->rx_prod_bseq); 4533 } 4534 4535 /****************************************************************************/ 4536 /* Reads the transmit consumer value from the status block (skipping over */ 4537 /* chain page pointer if necessary). */ 4538 /* */ 4539 /* Returns: */ 4540 /* hw_cons */ 4541 /****************************************************************************/ 4542 static __inline uint16_t 4543 bce_get_hw_tx_cons(struct bce_tx_ring *txr) 4544 { 4545 uint16_t hw_cons = *txr->tx_hw_cons; 4546 4547 if ((hw_cons & USABLE_TX_BD_PER_PAGE) == USABLE_TX_BD_PER_PAGE) 4548 hw_cons++; 4549 return hw_cons; 4550 } 4551 4552 /****************************************************************************/ 4553 /* Handles transmit completion interrupt events. */ 4554 /* */ 4555 /* Returns: */ 4556 /* Nothing. */ 4557 /****************************************************************************/ 4558 static void 4559 bce_tx_intr(struct bce_tx_ring *txr, uint16_t hw_tx_cons) 4560 { 4561 struct ifnet *ifp = &txr->sc->arpcom.ac_if; 4562 uint16_t sw_tx_cons, sw_tx_chain_cons; 4563 4564 ASSERT_SERIALIZED(&txr->tx_serialize); 4565 4566 /* Get the hardware's view of the TX consumer index. */ 4567 sw_tx_cons = txr->tx_cons; 4568 4569 /* Cycle through any completed TX chain page entries. */ 4570 while (sw_tx_cons != hw_tx_cons) { 4571 struct bce_tx_buf *tx_buf; 4572 4573 sw_tx_chain_cons = TX_CHAIN_IDX(txr, sw_tx_cons); 4574 tx_buf = &txr->tx_bufs[sw_tx_chain_cons]; 4575 4576 /* 4577 * Free the associated mbuf. Remember 4578 * that only the last tx_bd of a packet 4579 * has an mbuf pointer and DMA map. 4580 */ 4581 if (tx_buf->tx_mbuf_ptr != NULL) { 4582 /* Unmap the mbuf. */ 4583 bus_dmamap_unload(txr->tx_mbuf_tag, 4584 tx_buf->tx_mbuf_map); 4585 4586 /* Free the mbuf. */ 4587 m_freem(tx_buf->tx_mbuf_ptr); 4588 tx_buf->tx_mbuf_ptr = NULL; 4589 4590 IFNET_STAT_INC(ifp, opackets, 1); 4591 #ifdef BCE_TSS_DEBUG 4592 txr->tx_pkts++; 4593 #endif 4594 } 4595 4596 txr->used_tx_bd--; 4597 sw_tx_cons = NEXT_TX_BD(sw_tx_cons); 4598 } 4599 4600 if (txr->used_tx_bd == 0) { 4601 /* Clear the TX timeout timer. */ 4602 txr->tx_watchdog.wd_timer = 0; 4603 } 4604 4605 /* Clear the tx hardware queue full flag. */ 4606 if (txr->max_tx_bd - txr->used_tx_bd >= BCE_TX_SPARE_SPACE) 4607 ifsq_clr_oactive(txr->ifsq); 4608 txr->tx_cons = sw_tx_cons; 4609 } 4610 4611 /****************************************************************************/ 4612 /* Disables interrupt generation. */ 4613 /* */ 4614 /* Returns: */ 4615 /* Nothing. */ 4616 /****************************************************************************/ 4617 static void 4618 bce_disable_intr(struct bce_softc *sc) 4619 { 4620 int i; 4621 4622 for (i = 0; i < sc->rx_ring_cnt; ++i) { 4623 REG_WR(sc, BCE_PCICFG_INT_ACK_CMD, 4624 (sc->rx_rings[i].idx << 24) | 4625 BCE_PCICFG_INT_ACK_CMD_MASK_INT); 4626 } 4627 REG_RD(sc, BCE_PCICFG_INT_ACK_CMD); 4628 4629 callout_stop(&sc->bce_ckmsi_callout); 4630 sc->bce_msi_maylose = FALSE; 4631 sc->bce_check_rx_cons = 0; 4632 sc->bce_check_tx_cons = 0; 4633 sc->bce_check_status_idx = 0xffff; 4634 4635 for (i = 0; i < sc->rx_ring_cnt; ++i) 4636 lwkt_serialize_handler_disable(sc->bce_msix[i].msix_serialize); 4637 } 4638 4639 /****************************************************************************/ 4640 /* Enables interrupt generation. */ 4641 /* */ 4642 /* Returns: */ 4643 /* Nothing. */ 4644 /****************************************************************************/ 4645 static void 4646 bce_enable_intr(struct bce_softc *sc) 4647 { 4648 int i; 4649 4650 for (i = 0; i < sc->rx_ring_cnt; ++i) 4651 lwkt_serialize_handler_enable(sc->bce_msix[i].msix_serialize); 4652 4653 for (i = 0; i < sc->rx_ring_cnt; ++i) { 4654 struct bce_rx_ring *rxr = &sc->rx_rings[i]; 4655 4656 REG_WR(sc, BCE_PCICFG_INT_ACK_CMD, (rxr->idx << 24) | 4657 BCE_PCICFG_INT_ACK_CMD_INDEX_VALID | 4658 BCE_PCICFG_INT_ACK_CMD_MASK_INT | 4659 rxr->last_status_idx); 4660 REG_WR(sc, BCE_PCICFG_INT_ACK_CMD, (rxr->idx << 24) | 4661 BCE_PCICFG_INT_ACK_CMD_INDEX_VALID | 4662 rxr->last_status_idx); 4663 } 4664 REG_WR(sc, BCE_HC_COMMAND, sc->hc_command | BCE_HC_COMMAND_COAL_NOW); 4665 4666 if (sc->bce_flags & BCE_CHECK_MSI_FLAG) { 4667 sc->bce_msi_maylose = FALSE; 4668 sc->bce_check_rx_cons = 0; 4669 sc->bce_check_tx_cons = 0; 4670 sc->bce_check_status_idx = 0xffff; 4671 4672 if (bootverbose) 4673 if_printf(&sc->arpcom.ac_if, "check msi\n"); 4674 4675 callout_reset_bycpu(&sc->bce_ckmsi_callout, BCE_MSI_CKINTVL, 4676 bce_check_msi, sc, sc->bce_msix[0].msix_cpuid); 4677 } 4678 } 4679 4680 /****************************************************************************/ 4681 /* Reenables interrupt generation during interrupt handling. */ 4682 /* */ 4683 /* Returns: */ 4684 /* Nothing. */ 4685 /****************************************************************************/ 4686 static void 4687 bce_reenable_intr(struct bce_rx_ring *rxr) 4688 { 4689 REG_WR(rxr->sc, BCE_PCICFG_INT_ACK_CMD, (rxr->idx << 24) | 4690 BCE_PCICFG_INT_ACK_CMD_INDEX_VALID | rxr->last_status_idx); 4691 } 4692 4693 /****************************************************************************/ 4694 /* Handles controller initialization. */ 4695 /* */ 4696 /* Returns: */ 4697 /* Nothing. */ 4698 /****************************************************************************/ 4699 static void 4700 bce_init(void *xsc) 4701 { 4702 struct bce_softc *sc = xsc; 4703 struct ifnet *ifp = &sc->arpcom.ac_if; 4704 uint32_t ether_mtu; 4705 int error, i; 4706 boolean_t polling; 4707 4708 ASSERT_IFNET_SERIALIZED_ALL(ifp); 4709 4710 /* Check if the driver is still running and bail out if it is. */ 4711 if (ifp->if_flags & IFF_RUNNING) 4712 return; 4713 4714 bce_stop(sc); 4715 4716 error = bce_reset(sc, BCE_DRV_MSG_CODE_RESET); 4717 if (error) { 4718 if_printf(ifp, "Controller reset failed!\n"); 4719 goto back; 4720 } 4721 4722 error = bce_chipinit(sc); 4723 if (error) { 4724 if_printf(ifp, "Controller initialization failed!\n"); 4725 goto back; 4726 } 4727 4728 error = bce_blockinit(sc); 4729 if (error) { 4730 if_printf(ifp, "Block initialization failed!\n"); 4731 goto back; 4732 } 4733 4734 /* Load our MAC address. */ 4735 bcopy(IF_LLADDR(ifp), sc->eaddr, ETHER_ADDR_LEN); 4736 bce_set_mac_addr(sc); 4737 4738 /* Calculate and program the Ethernet MTU size. */ 4739 ether_mtu = ETHER_HDR_LEN + EVL_ENCAPLEN + ifp->if_mtu + ETHER_CRC_LEN; 4740 4741 /* 4742 * Program the mtu, enabling jumbo frame 4743 * support if necessary. Also set the mbuf 4744 * allocation count for RX frames. 4745 */ 4746 if (ether_mtu > ETHER_MAX_LEN + EVL_ENCAPLEN) { 4747 #ifdef notyet 4748 REG_WR(sc, BCE_EMAC_RX_MTU_SIZE, 4749 min(ether_mtu, BCE_MAX_JUMBO_ETHER_MTU) | 4750 BCE_EMAC_RX_MTU_SIZE_JUMBO_ENA); 4751 #else 4752 panic("jumbo buffer is not supported yet"); 4753 #endif 4754 } else { 4755 REG_WR(sc, BCE_EMAC_RX_MTU_SIZE, ether_mtu); 4756 } 4757 4758 /* Program appropriate promiscuous/multicast filtering. */ 4759 bce_set_rx_mode(sc); 4760 4761 /* 4762 * Init RX buffer descriptor chain. 4763 */ 4764 REG_WR(sc, BCE_RLUP_RSS_CONFIG, 0); 4765 bce_reg_wr_ind(sc, BCE_RXP_SCRATCH_RSS_TBL_SZ, 0); 4766 4767 for (i = 0; i < sc->rx_ring_cnt; ++i) 4768 bce_init_rx_chain(&sc->rx_rings[i]); /* XXX return value */ 4769 4770 if (sc->rx_ring_cnt > 1) 4771 bce_init_rss(sc); 4772 4773 /* 4774 * Init TX buffer descriptor chain. 4775 */ 4776 REG_WR(sc, BCE_TSCH_TSS_CFG, 0); 4777 4778 for (i = 0; i < sc->tx_ring_cnt; ++i) 4779 bce_init_tx_chain(&sc->tx_rings[i]); 4780 4781 if (sc->tx_ring_cnt > 1) { 4782 REG_WR(sc, BCE_TSCH_TSS_CFG, 4783 ((sc->tx_ring_cnt - 1) << 24) | (TX_TSS_CID << 7)); 4784 } 4785 4786 polling = FALSE; 4787 #ifdef IFPOLL_ENABLE 4788 if (ifp->if_flags & IFF_NPOLLING) 4789 polling = TRUE; 4790 #endif 4791 4792 if (polling) { 4793 /* Disable interrupts if we are polling. */ 4794 bce_disable_intr(sc); 4795 4796 /* Change coalesce parameters */ 4797 bce_npoll_coal_change(sc); 4798 } else { 4799 /* Enable host interrupts. */ 4800 bce_enable_intr(sc); 4801 } 4802 bce_set_timer_cpuid(sc, polling); 4803 4804 bce_ifmedia_upd(ifp); 4805 4806 ifp->if_flags |= IFF_RUNNING; 4807 for (i = 0; i < sc->tx_ring_cnt; ++i) { 4808 ifsq_clr_oactive(sc->tx_rings[i].ifsq); 4809 ifsq_watchdog_start(&sc->tx_rings[i].tx_watchdog); 4810 } 4811 4812 callout_reset_bycpu(&sc->bce_tick_callout, hz, bce_tick, sc, 4813 sc->bce_timer_cpuid); 4814 back: 4815 if (error) 4816 bce_stop(sc); 4817 } 4818 4819 /****************************************************************************/ 4820 /* Initialize the controller just enough so that any management firmware */ 4821 /* running on the device will continue to operate corectly. */ 4822 /* */ 4823 /* Returns: */ 4824 /* Nothing. */ 4825 /****************************************************************************/ 4826 static void 4827 bce_mgmt_init(struct bce_softc *sc) 4828 { 4829 struct ifnet *ifp = &sc->arpcom.ac_if; 4830 4831 /* Bail out if management firmware is not running. */ 4832 if (!(sc->bce_flags & BCE_MFW_ENABLE_FLAG)) 4833 return; 4834 4835 /* Enable all critical blocks in the MAC. */ 4836 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 4837 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 4838 REG_WR(sc, BCE_MISC_ENABLE_SET_BITS, 4839 BCE_MISC_ENABLE_DEFAULT_XI); 4840 } else { 4841 REG_WR(sc, BCE_MISC_ENABLE_SET_BITS, BCE_MISC_ENABLE_DEFAULT); 4842 } 4843 REG_RD(sc, BCE_MISC_ENABLE_SET_BITS); 4844 DELAY(20); 4845 4846 bce_ifmedia_upd(ifp); 4847 } 4848 4849 /****************************************************************************/ 4850 /* Encapsultes an mbuf cluster into the tx_bd chain structure and makes the */ 4851 /* memory visible to the controller. */ 4852 /* */ 4853 /* Returns: */ 4854 /* 0 for success, positive value for failure. */ 4855 /****************************************************************************/ 4856 static int 4857 bce_encap(struct bce_tx_ring *txr, struct mbuf **m_head, int *nsegs_used) 4858 { 4859 bus_dma_segment_t segs[BCE_MAX_SEGMENTS]; 4860 bus_dmamap_t map, tmp_map; 4861 struct mbuf *m0 = *m_head; 4862 struct tx_bd *txbd = NULL; 4863 uint16_t vlan_tag = 0, flags = 0, mss = 0; 4864 uint16_t chain_prod, chain_prod_start, prod; 4865 uint32_t prod_bseq; 4866 int i, error, maxsegs, nsegs; 4867 4868 /* Transfer any checksum offload flags to the bd. */ 4869 if (m0->m_pkthdr.csum_flags & CSUM_TSO) { 4870 error = bce_tso_setup(txr, m_head, &flags, &mss); 4871 if (error) 4872 return ENOBUFS; 4873 m0 = *m_head; 4874 } else if (m0->m_pkthdr.csum_flags & BCE_CSUM_FEATURES) { 4875 if (m0->m_pkthdr.csum_flags & CSUM_IP) 4876 flags |= TX_BD_FLAGS_IP_CKSUM; 4877 if (m0->m_pkthdr.csum_flags & (CSUM_TCP | CSUM_UDP)) 4878 flags |= TX_BD_FLAGS_TCP_UDP_CKSUM; 4879 } 4880 4881 /* Transfer any VLAN tags to the bd. */ 4882 if (m0->m_flags & M_VLANTAG) { 4883 flags |= TX_BD_FLAGS_VLAN_TAG; 4884 vlan_tag = m0->m_pkthdr.ether_vlantag; 4885 } 4886 4887 prod = txr->tx_prod; 4888 chain_prod_start = chain_prod = TX_CHAIN_IDX(txr, prod); 4889 4890 /* Map the mbuf into DMAable memory. */ 4891 map = txr->tx_bufs[chain_prod_start].tx_mbuf_map; 4892 4893 maxsegs = txr->max_tx_bd - txr->used_tx_bd; 4894 KASSERT(maxsegs >= BCE_TX_SPARE_SPACE, 4895 ("not enough segments %d", maxsegs)); 4896 if (maxsegs > BCE_MAX_SEGMENTS) 4897 maxsegs = BCE_MAX_SEGMENTS; 4898 4899 /* Map the mbuf into our DMA address space. */ 4900 error = bus_dmamap_load_mbuf_defrag(txr->tx_mbuf_tag, map, m_head, 4901 segs, maxsegs, &nsegs, BUS_DMA_NOWAIT); 4902 if (error) 4903 goto back; 4904 bus_dmamap_sync(txr->tx_mbuf_tag, map, BUS_DMASYNC_PREWRITE); 4905 4906 *nsegs_used += nsegs; 4907 4908 /* Reset m0 */ 4909 m0 = *m_head; 4910 4911 /* prod points to an empty tx_bd at this point. */ 4912 prod_bseq = txr->tx_prod_bseq; 4913 4914 /* 4915 * Cycle through each mbuf segment that makes up 4916 * the outgoing frame, gathering the mapping info 4917 * for that segment and creating a tx_bd to for 4918 * the mbuf. 4919 */ 4920 for (i = 0; i < nsegs; i++) { 4921 chain_prod = TX_CHAIN_IDX(txr, prod); 4922 txbd = 4923 &txr->tx_bd_chain[TX_PAGE(chain_prod)][TX_IDX(chain_prod)]; 4924 4925 txbd->tx_bd_haddr_lo = htole32(BCE_ADDR_LO(segs[i].ds_addr)); 4926 txbd->tx_bd_haddr_hi = htole32(BCE_ADDR_HI(segs[i].ds_addr)); 4927 txbd->tx_bd_mss_nbytes = htole32(mss << 16) | 4928 htole16(segs[i].ds_len); 4929 txbd->tx_bd_vlan_tag = htole16(vlan_tag); 4930 txbd->tx_bd_flags = htole16(flags); 4931 4932 prod_bseq += segs[i].ds_len; 4933 if (i == 0) 4934 txbd->tx_bd_flags |= htole16(TX_BD_FLAGS_START); 4935 prod = NEXT_TX_BD(prod); 4936 } 4937 4938 /* Set the END flag on the last TX buffer descriptor. */ 4939 txbd->tx_bd_flags |= htole16(TX_BD_FLAGS_END); 4940 4941 /* 4942 * Ensure that the mbuf pointer for this transmission 4943 * is placed at the array index of the last 4944 * descriptor in this chain. This is done 4945 * because a single map is used for all 4946 * segments of the mbuf and we don't want to 4947 * unload the map before all of the segments 4948 * have been freed. 4949 */ 4950 txr->tx_bufs[chain_prod].tx_mbuf_ptr = m0; 4951 4952 tmp_map = txr->tx_bufs[chain_prod].tx_mbuf_map; 4953 txr->tx_bufs[chain_prod].tx_mbuf_map = map; 4954 txr->tx_bufs[chain_prod_start].tx_mbuf_map = tmp_map; 4955 4956 txr->used_tx_bd += nsegs; 4957 4958 /* prod points to the next free tx_bd at this point. */ 4959 txr->tx_prod = prod; 4960 txr->tx_prod_bseq = prod_bseq; 4961 back: 4962 if (error) { 4963 m_freem(*m_head); 4964 *m_head = NULL; 4965 } 4966 return error; 4967 } 4968 4969 static void 4970 bce_xmit(struct bce_tx_ring *txr) 4971 { 4972 /* Start the transmit. */ 4973 REG_WR16(txr->sc, MB_GET_CID_ADDR(txr->tx_cid) + BCE_L2CTX_TX_HOST_BIDX, 4974 txr->tx_prod); 4975 REG_WR(txr->sc, MB_GET_CID_ADDR(txr->tx_cid) + BCE_L2CTX_TX_HOST_BSEQ, 4976 txr->tx_prod_bseq); 4977 } 4978 4979 /****************************************************************************/ 4980 /* Main transmit routine when called from another routine with a lock. */ 4981 /* */ 4982 /* Returns: */ 4983 /* Nothing. */ 4984 /****************************************************************************/ 4985 static void 4986 bce_start(struct ifnet *ifp, struct ifaltq_subque *ifsq) 4987 { 4988 struct bce_softc *sc = ifp->if_softc; 4989 struct bce_tx_ring *txr = ifsq_get_priv(ifsq); 4990 int count = 0; 4991 4992 KKASSERT(txr->ifsq == ifsq); 4993 ASSERT_SERIALIZED(&txr->tx_serialize); 4994 4995 /* If there's no link or the transmit queue is empty then just exit. */ 4996 if (!sc->bce_link) { 4997 ifsq_purge(ifsq); 4998 return; 4999 } 5000 5001 if ((ifp->if_flags & IFF_RUNNING) == 0 || ifsq_is_oactive(ifsq)) 5002 return; 5003 5004 for (;;) { 5005 struct mbuf *m_head; 5006 5007 /* 5008 * We keep BCE_TX_SPARE_SPACE entries, so bce_encap() is 5009 * unlikely to fail. 5010 */ 5011 if (txr->max_tx_bd - txr->used_tx_bd < BCE_TX_SPARE_SPACE) { 5012 ifsq_set_oactive(ifsq); 5013 break; 5014 } 5015 5016 /* Check for any frames to send. */ 5017 m_head = ifsq_dequeue(ifsq); 5018 if (m_head == NULL) 5019 break; 5020 5021 /* 5022 * Pack the data into the transmit ring. If we 5023 * don't have room, place the mbuf back at the 5024 * head of the queue and set the OACTIVE flag 5025 * to wait for the NIC to drain the chain. 5026 */ 5027 if (bce_encap(txr, &m_head, &count)) { 5028 IFNET_STAT_INC(ifp, oerrors, 1); 5029 if (txr->used_tx_bd == 0) { 5030 continue; 5031 } else { 5032 ifsq_set_oactive(ifsq); 5033 break; 5034 } 5035 } 5036 5037 if (count >= txr->tx_wreg) { 5038 bce_xmit(txr); 5039 count = 0; 5040 } 5041 5042 /* Send a copy of the frame to any BPF listeners. */ 5043 ETHER_BPF_MTAP(ifp, m_head); 5044 5045 /* Set the tx timeout. */ 5046 txr->tx_watchdog.wd_timer = BCE_TX_TIMEOUT; 5047 } 5048 if (count > 0) 5049 bce_xmit(txr); 5050 } 5051 5052 /****************************************************************************/ 5053 /* Handles any IOCTL calls from the operating system. */ 5054 /* */ 5055 /* Returns: */ 5056 /* 0 for success, positive value for failure. */ 5057 /****************************************************************************/ 5058 static int 5059 bce_ioctl(struct ifnet *ifp, u_long command, caddr_t data, struct ucred *cr) 5060 { 5061 struct bce_softc *sc = ifp->if_softc; 5062 struct ifreq *ifr = (struct ifreq *)data; 5063 struct mii_data *mii; 5064 int mask, error = 0; 5065 5066 ASSERT_IFNET_SERIALIZED_ALL(ifp); 5067 5068 switch(command) { 5069 case SIOCSIFMTU: 5070 /* Check that the MTU setting is supported. */ 5071 if (ifr->ifr_mtu < BCE_MIN_MTU || 5072 #ifdef notyet 5073 ifr->ifr_mtu > BCE_MAX_JUMBO_MTU 5074 #else 5075 ifr->ifr_mtu > ETHERMTU 5076 #endif 5077 ) { 5078 error = EINVAL; 5079 break; 5080 } 5081 5082 ifp->if_mtu = ifr->ifr_mtu; 5083 ifp->if_flags &= ~IFF_RUNNING; /* Force reinitialize */ 5084 bce_init(sc); 5085 break; 5086 5087 case SIOCSIFFLAGS: 5088 if (ifp->if_flags & IFF_UP) { 5089 if (ifp->if_flags & IFF_RUNNING) { 5090 mask = ifp->if_flags ^ sc->bce_if_flags; 5091 5092 if (mask & (IFF_PROMISC | IFF_ALLMULTI)) 5093 bce_set_rx_mode(sc); 5094 } else { 5095 bce_init(sc); 5096 } 5097 } else if (ifp->if_flags & IFF_RUNNING) { 5098 bce_stop(sc); 5099 5100 /* If MFW is running, restart the controller a bit. */ 5101 if (sc->bce_flags & BCE_MFW_ENABLE_FLAG) { 5102 bce_reset(sc, BCE_DRV_MSG_CODE_RESET); 5103 bce_chipinit(sc); 5104 bce_mgmt_init(sc); 5105 } 5106 } 5107 sc->bce_if_flags = ifp->if_flags; 5108 break; 5109 5110 case SIOCADDMULTI: 5111 case SIOCDELMULTI: 5112 if (ifp->if_flags & IFF_RUNNING) 5113 bce_set_rx_mode(sc); 5114 break; 5115 5116 case SIOCSIFMEDIA: 5117 case SIOCGIFMEDIA: 5118 mii = device_get_softc(sc->bce_miibus); 5119 error = ifmedia_ioctl(ifp, ifr, &mii->mii_media, command); 5120 break; 5121 5122 case SIOCSIFCAP: 5123 mask = ifr->ifr_reqcap ^ ifp->if_capenable; 5124 if (mask & IFCAP_HWCSUM) { 5125 ifp->if_capenable ^= (mask & IFCAP_HWCSUM); 5126 if (ifp->if_capenable & IFCAP_TXCSUM) 5127 ifp->if_hwassist |= BCE_CSUM_FEATURES; 5128 else 5129 ifp->if_hwassist &= ~BCE_CSUM_FEATURES; 5130 } 5131 if (mask & IFCAP_TSO) { 5132 ifp->if_capenable ^= IFCAP_TSO; 5133 if (ifp->if_capenable & IFCAP_TSO) 5134 ifp->if_hwassist |= CSUM_TSO; 5135 else 5136 ifp->if_hwassist &= ~CSUM_TSO; 5137 } 5138 if (mask & IFCAP_RSS) 5139 ifp->if_capenable ^= IFCAP_RSS; 5140 break; 5141 5142 default: 5143 error = ether_ioctl(ifp, command, data); 5144 break; 5145 } 5146 return error; 5147 } 5148 5149 /****************************************************************************/ 5150 /* Transmit timeout handler. */ 5151 /* */ 5152 /* Returns: */ 5153 /* Nothing. */ 5154 /****************************************************************************/ 5155 static void 5156 bce_watchdog(struct ifaltq_subque *ifsq) 5157 { 5158 struct ifnet *ifp = ifsq_get_ifp(ifsq); 5159 struct bce_softc *sc = ifp->if_softc; 5160 int i; 5161 5162 ASSERT_IFNET_SERIALIZED_ALL(ifp); 5163 5164 /* 5165 * If we are in this routine because of pause frames, then 5166 * don't reset the hardware. 5167 */ 5168 if (REG_RD(sc, BCE_EMAC_TX_STATUS) & BCE_EMAC_TX_STATUS_XOFFED) 5169 return; 5170 5171 if_printf(ifp, "Watchdog timeout occurred, resetting!\n"); 5172 5173 ifp->if_flags &= ~IFF_RUNNING; /* Force reinitialize */ 5174 bce_init(sc); 5175 5176 IFNET_STAT_INC(ifp, oerrors, 1); 5177 5178 for (i = 0; i < sc->tx_ring_cnt; ++i) 5179 ifsq_devstart_sched(sc->tx_rings[i].ifsq); 5180 } 5181 5182 #ifdef IFPOLL_ENABLE 5183 5184 static void 5185 bce_npoll_status(struct ifnet *ifp) 5186 { 5187 struct bce_softc *sc = ifp->if_softc; 5188 struct status_block *sblk = sc->status_block; 5189 uint32_t status_attn_bits; 5190 5191 ASSERT_SERIALIZED(&sc->main_serialize); 5192 5193 status_attn_bits = sblk->status_attn_bits; 5194 5195 /* Was it a link change interrupt? */ 5196 if ((status_attn_bits & STATUS_ATTN_BITS_LINK_STATE) != 5197 (sblk->status_attn_bits_ack & STATUS_ATTN_BITS_LINK_STATE)) { 5198 bce_phy_intr(sc); 5199 5200 /* 5201 * Clear any transient status updates during link state change. 5202 */ 5203 REG_WR(sc, BCE_HC_COMMAND, 5204 sc->hc_command | BCE_HC_COMMAND_COAL_NOW_WO_INT); 5205 REG_RD(sc, BCE_HC_COMMAND); 5206 } 5207 5208 /* 5209 * If any other attention is asserted then the chip is toast. 5210 */ 5211 if ((status_attn_bits & ~STATUS_ATTN_BITS_LINK_STATE) != 5212 (sblk->status_attn_bits_ack & ~STATUS_ATTN_BITS_LINK_STATE)) { 5213 if_printf(ifp, "Fatal attention detected: 0x%08X\n", 5214 sblk->status_attn_bits); 5215 bce_serialize_skipmain(sc); 5216 bce_init(sc); 5217 bce_deserialize_skipmain(sc); 5218 } 5219 } 5220 5221 static void 5222 bce_npoll_rx(struct ifnet *ifp, void *arg, int count) 5223 { 5224 struct bce_rx_ring *rxr = arg; 5225 uint16_t hw_rx_cons; 5226 5227 ASSERT_SERIALIZED(&rxr->rx_serialize); 5228 5229 /* 5230 * Save the status block index value for use when enabling 5231 * the interrupt. 5232 */ 5233 rxr->last_status_idx = *rxr->hw_status_idx; 5234 5235 /* Make sure status index is extracted before RX/TX cons */ 5236 cpu_lfence(); 5237 5238 hw_rx_cons = bce_get_hw_rx_cons(rxr); 5239 5240 /* Check for any completed RX frames. */ 5241 if (hw_rx_cons != rxr->rx_cons) 5242 bce_rx_intr(rxr, count, hw_rx_cons); 5243 } 5244 5245 static void 5246 bce_npoll_rx_pack(struct ifnet *ifp, void *arg, int count) 5247 { 5248 struct bce_rx_ring *rxr = arg; 5249 5250 KASSERT(rxr->idx == 0, ("not the first RX ring, but %d", rxr->idx)); 5251 bce_npoll_rx(ifp, rxr, count); 5252 5253 KASSERT(rxr->sc->rx_ring_cnt != rxr->sc->rx_ring_cnt2, 5254 ("RX ring count %d, count2 %d", rxr->sc->rx_ring_cnt, 5255 rxr->sc->rx_ring_cnt2)); 5256 5257 /* Last ring carries packets whose masked hash is 0 */ 5258 rxr = &rxr->sc->rx_rings[rxr->sc->rx_ring_cnt - 1]; 5259 5260 lwkt_serialize_enter(&rxr->rx_serialize); 5261 bce_npoll_rx(ifp, rxr, count); 5262 lwkt_serialize_exit(&rxr->rx_serialize); 5263 } 5264 5265 static void 5266 bce_npoll_tx(struct ifnet *ifp, void *arg, int count __unused) 5267 { 5268 struct bce_tx_ring *txr = arg; 5269 uint16_t hw_tx_cons; 5270 5271 ASSERT_SERIALIZED(&txr->tx_serialize); 5272 5273 hw_tx_cons = bce_get_hw_tx_cons(txr); 5274 5275 /* Check for any completed TX frames. */ 5276 if (hw_tx_cons != txr->tx_cons) { 5277 bce_tx_intr(txr, hw_tx_cons); 5278 if (!ifsq_is_empty(txr->ifsq)) 5279 ifsq_devstart(txr->ifsq); 5280 } 5281 } 5282 5283 static void 5284 bce_npoll(struct ifnet *ifp, struct ifpoll_info *info) 5285 { 5286 struct bce_softc *sc = ifp->if_softc; 5287 int i; 5288 5289 ASSERT_IFNET_SERIALIZED_ALL(ifp); 5290 5291 if (info != NULL) { 5292 info->ifpi_status.status_func = bce_npoll_status; 5293 info->ifpi_status.serializer = &sc->main_serialize; 5294 5295 for (i = 0; i < sc->tx_ring_cnt; ++i) { 5296 struct bce_tx_ring *txr = &sc->tx_rings[i]; 5297 int idx = i + sc->npoll_ofs; 5298 5299 KKASSERT(idx < ncpus2); 5300 info->ifpi_tx[idx].poll_func = bce_npoll_tx; 5301 info->ifpi_tx[idx].arg = txr; 5302 info->ifpi_tx[idx].serializer = &txr->tx_serialize; 5303 ifsq_set_cpuid(txr->ifsq, idx); 5304 } 5305 5306 for (i = 0; i < sc->rx_ring_cnt2; ++i) { 5307 struct bce_rx_ring *rxr = &sc->rx_rings[i]; 5308 int idx = i + sc->npoll_ofs; 5309 5310 KKASSERT(idx < ncpus2); 5311 if (i == 0 && sc->rx_ring_cnt2 != sc->rx_ring_cnt) { 5312 /* 5313 * If RSS is enabled, the packets whose 5314 * masked hash are 0 are queued to the 5315 * last RX ring; piggyback the last RX 5316 * ring's processing in the first RX 5317 * polling handler. (see also: comment 5318 * in bce_setup_ring_cnt()) 5319 */ 5320 if (bootverbose) { 5321 if_printf(ifp, "npoll pack last " 5322 "RX ring on cpu%d\n", idx); 5323 } 5324 info->ifpi_rx[idx].poll_func = 5325 bce_npoll_rx_pack; 5326 } else { 5327 info->ifpi_rx[idx].poll_func = bce_npoll_rx; 5328 } 5329 info->ifpi_rx[idx].arg = rxr; 5330 info->ifpi_rx[idx].serializer = &rxr->rx_serialize; 5331 } 5332 5333 if (ifp->if_flags & IFF_RUNNING) { 5334 bce_set_timer_cpuid(sc, TRUE); 5335 bce_disable_intr(sc); 5336 bce_npoll_coal_change(sc); 5337 } 5338 } else { 5339 for (i = 0; i < sc->tx_ring_cnt; ++i) { 5340 ifsq_set_cpuid(sc->tx_rings[i].ifsq, 5341 sc->bce_msix[i].msix_cpuid); 5342 } 5343 5344 if (ifp->if_flags & IFF_RUNNING) { 5345 bce_set_timer_cpuid(sc, FALSE); 5346 bce_enable_intr(sc); 5347 5348 sc->bce_coalchg_mask |= BCE_COALMASK_TX_BDS_INT | 5349 BCE_COALMASK_RX_BDS_INT; 5350 bce_coal_change(sc); 5351 } 5352 } 5353 } 5354 5355 #endif /* IFPOLL_ENABLE */ 5356 5357 /* 5358 * Interrupt handler. 5359 */ 5360 /****************************************************************************/ 5361 /* Main interrupt entry point. Verifies that the controller generated the */ 5362 /* interrupt and then calls a separate routine for handle the various */ 5363 /* interrupt causes (PHY, TX, RX). */ 5364 /* */ 5365 /* Returns: */ 5366 /* 0 for success, positive value for failure. */ 5367 /****************************************************************************/ 5368 static void 5369 bce_intr(struct bce_softc *sc) 5370 { 5371 struct ifnet *ifp = &sc->arpcom.ac_if; 5372 struct status_block *sblk; 5373 uint16_t hw_rx_cons, hw_tx_cons; 5374 uint32_t status_attn_bits; 5375 struct bce_tx_ring *txr = &sc->tx_rings[0]; 5376 struct bce_rx_ring *rxr = &sc->rx_rings[0]; 5377 5378 ASSERT_SERIALIZED(&sc->main_serialize); 5379 5380 sblk = sc->status_block; 5381 5382 /* 5383 * Save the status block index value for use during 5384 * the next interrupt. 5385 */ 5386 rxr->last_status_idx = *rxr->hw_status_idx; 5387 5388 /* Make sure status index is extracted before RX/TX cons */ 5389 cpu_lfence(); 5390 5391 /* Check if the hardware has finished any work. */ 5392 hw_rx_cons = bce_get_hw_rx_cons(rxr); 5393 hw_tx_cons = bce_get_hw_tx_cons(txr); 5394 5395 status_attn_bits = sblk->status_attn_bits; 5396 5397 /* Was it a link change interrupt? */ 5398 if ((status_attn_bits & STATUS_ATTN_BITS_LINK_STATE) != 5399 (sblk->status_attn_bits_ack & STATUS_ATTN_BITS_LINK_STATE)) { 5400 bce_phy_intr(sc); 5401 5402 /* 5403 * Clear any transient status updates during link state 5404 * change. 5405 */ 5406 REG_WR(sc, BCE_HC_COMMAND, 5407 sc->hc_command | BCE_HC_COMMAND_COAL_NOW_WO_INT); 5408 REG_RD(sc, BCE_HC_COMMAND); 5409 } 5410 5411 /* 5412 * If any other attention is asserted then 5413 * the chip is toast. 5414 */ 5415 if ((status_attn_bits & ~STATUS_ATTN_BITS_LINK_STATE) != 5416 (sblk->status_attn_bits_ack & ~STATUS_ATTN_BITS_LINK_STATE)) { 5417 if_printf(ifp, "Fatal attention detected: 0x%08X\n", 5418 sblk->status_attn_bits); 5419 bce_serialize_skipmain(sc); 5420 bce_init(sc); 5421 bce_deserialize_skipmain(sc); 5422 return; 5423 } 5424 5425 /* Check for any completed RX frames. */ 5426 lwkt_serialize_enter(&rxr->rx_serialize); 5427 if (hw_rx_cons != rxr->rx_cons) 5428 bce_rx_intr(rxr, -1, hw_rx_cons); 5429 lwkt_serialize_exit(&rxr->rx_serialize); 5430 5431 /* Check for any completed TX frames. */ 5432 lwkt_serialize_enter(&txr->tx_serialize); 5433 if (hw_tx_cons != txr->tx_cons) { 5434 bce_tx_intr(txr, hw_tx_cons); 5435 if (!ifsq_is_empty(txr->ifsq)) 5436 ifsq_devstart(txr->ifsq); 5437 } 5438 lwkt_serialize_exit(&txr->tx_serialize); 5439 } 5440 5441 static void 5442 bce_intr_legacy(void *xsc) 5443 { 5444 struct bce_softc *sc = xsc; 5445 struct bce_rx_ring *rxr = &sc->rx_rings[0]; 5446 struct status_block *sblk; 5447 5448 sblk = sc->status_block; 5449 5450 /* 5451 * If the hardware status block index matches the last value 5452 * read by the driver and we haven't asserted our interrupt 5453 * then there's nothing to do. 5454 */ 5455 if (sblk->status_idx == rxr->last_status_idx && 5456 (REG_RD(sc, BCE_PCICFG_MISC_STATUS) & 5457 BCE_PCICFG_MISC_STATUS_INTA_VALUE)) 5458 return; 5459 5460 /* Ack the interrupt and stop others from occuring. */ 5461 REG_WR(sc, BCE_PCICFG_INT_ACK_CMD, 5462 BCE_PCICFG_INT_ACK_CMD_USE_INT_HC_PARAM | 5463 BCE_PCICFG_INT_ACK_CMD_MASK_INT); 5464 5465 /* 5466 * Read back to deassert IRQ immediately to avoid too 5467 * many spurious interrupts. 5468 */ 5469 REG_RD(sc, BCE_PCICFG_INT_ACK_CMD); 5470 5471 bce_intr(sc); 5472 5473 /* Re-enable interrupts. */ 5474 REG_WR(sc, BCE_PCICFG_INT_ACK_CMD, 5475 BCE_PCICFG_INT_ACK_CMD_INDEX_VALID | 5476 BCE_PCICFG_INT_ACK_CMD_MASK_INT | rxr->last_status_idx); 5477 bce_reenable_intr(rxr); 5478 } 5479 5480 static void 5481 bce_intr_msi(void *xsc) 5482 { 5483 struct bce_softc *sc = xsc; 5484 5485 /* Ack the interrupt and stop others from occuring. */ 5486 REG_WR(sc, BCE_PCICFG_INT_ACK_CMD, 5487 BCE_PCICFG_INT_ACK_CMD_USE_INT_HC_PARAM | 5488 BCE_PCICFG_INT_ACK_CMD_MASK_INT); 5489 5490 bce_intr(sc); 5491 5492 /* Re-enable interrupts */ 5493 bce_reenable_intr(&sc->rx_rings[0]); 5494 } 5495 5496 static void 5497 bce_intr_msi_oneshot(void *xsc) 5498 { 5499 struct bce_softc *sc = xsc; 5500 5501 bce_intr(sc); 5502 5503 /* Re-enable interrupts */ 5504 bce_reenable_intr(&sc->rx_rings[0]); 5505 } 5506 5507 static void 5508 bce_intr_msix_rxtx(void *xrxr) 5509 { 5510 struct bce_rx_ring *rxr = xrxr; 5511 struct bce_tx_ring *txr; 5512 uint16_t hw_rx_cons, hw_tx_cons; 5513 5514 ASSERT_SERIALIZED(&rxr->rx_serialize); 5515 5516 KKASSERT(rxr->idx < rxr->sc->tx_ring_cnt); 5517 txr = &rxr->sc->tx_rings[rxr->idx]; 5518 5519 /* 5520 * Save the status block index value for use during 5521 * the next interrupt. 5522 */ 5523 rxr->last_status_idx = *rxr->hw_status_idx; 5524 5525 /* Make sure status index is extracted before RX/TX cons */ 5526 cpu_lfence(); 5527 5528 /* Check if the hardware has finished any work. */ 5529 hw_rx_cons = bce_get_hw_rx_cons(rxr); 5530 if (hw_rx_cons != rxr->rx_cons) 5531 bce_rx_intr(rxr, -1, hw_rx_cons); 5532 5533 /* Check for any completed TX frames. */ 5534 hw_tx_cons = bce_get_hw_tx_cons(txr); 5535 lwkt_serialize_enter(&txr->tx_serialize); 5536 if (hw_tx_cons != txr->tx_cons) { 5537 bce_tx_intr(txr, hw_tx_cons); 5538 if (!ifsq_is_empty(txr->ifsq)) 5539 ifsq_devstart(txr->ifsq); 5540 } 5541 lwkt_serialize_exit(&txr->tx_serialize); 5542 5543 /* Re-enable interrupts */ 5544 bce_reenable_intr(rxr); 5545 } 5546 5547 static void 5548 bce_intr_msix_rx(void *xrxr) 5549 { 5550 struct bce_rx_ring *rxr = xrxr; 5551 uint16_t hw_rx_cons; 5552 5553 ASSERT_SERIALIZED(&rxr->rx_serialize); 5554 5555 /* 5556 * Save the status block index value for use during 5557 * the next interrupt. 5558 */ 5559 rxr->last_status_idx = *rxr->hw_status_idx; 5560 5561 /* Make sure status index is extracted before RX cons */ 5562 cpu_lfence(); 5563 5564 /* Check if the hardware has finished any work. */ 5565 hw_rx_cons = bce_get_hw_rx_cons(rxr); 5566 if (hw_rx_cons != rxr->rx_cons) 5567 bce_rx_intr(rxr, -1, hw_rx_cons); 5568 5569 /* Re-enable interrupts */ 5570 bce_reenable_intr(rxr); 5571 } 5572 5573 /****************************************************************************/ 5574 /* Programs the various packet receive modes (broadcast and multicast). */ 5575 /* */ 5576 /* Returns: */ 5577 /* Nothing. */ 5578 /****************************************************************************/ 5579 static void 5580 bce_set_rx_mode(struct bce_softc *sc) 5581 { 5582 struct ifnet *ifp = &sc->arpcom.ac_if; 5583 struct ifmultiaddr *ifma; 5584 uint32_t hashes[NUM_MC_HASH_REGISTERS] = { 0, 0, 0, 0, 0, 0, 0, 0 }; 5585 uint32_t rx_mode, sort_mode; 5586 int h, i; 5587 5588 ASSERT_IFNET_SERIALIZED_ALL(ifp); 5589 5590 /* Initialize receive mode default settings. */ 5591 rx_mode = sc->rx_mode & 5592 ~(BCE_EMAC_RX_MODE_PROMISCUOUS | 5593 BCE_EMAC_RX_MODE_KEEP_VLAN_TAG); 5594 sort_mode = 1 | BCE_RPM_SORT_USER0_BC_EN; 5595 5596 /* 5597 * ASF/IPMI/UMP firmware requires that VLAN tag stripping 5598 * be enbled. 5599 */ 5600 if (!(BCE_IF_CAPABILITIES & IFCAP_VLAN_HWTAGGING) && 5601 !(sc->bce_flags & BCE_MFW_ENABLE_FLAG)) 5602 rx_mode |= BCE_EMAC_RX_MODE_KEEP_VLAN_TAG; 5603 5604 /* 5605 * Check for promiscuous, all multicast, or selected 5606 * multicast address filtering. 5607 */ 5608 if (ifp->if_flags & IFF_PROMISC) { 5609 /* Enable promiscuous mode. */ 5610 rx_mode |= BCE_EMAC_RX_MODE_PROMISCUOUS; 5611 sort_mode |= BCE_RPM_SORT_USER0_PROM_EN; 5612 } else if (ifp->if_flags & IFF_ALLMULTI) { 5613 /* Enable all multicast addresses. */ 5614 for (i = 0; i < NUM_MC_HASH_REGISTERS; i++) { 5615 REG_WR(sc, BCE_EMAC_MULTICAST_HASH0 + (i * 4), 5616 0xffffffff); 5617 } 5618 sort_mode |= BCE_RPM_SORT_USER0_MC_EN; 5619 } else { 5620 /* Accept one or more multicast(s). */ 5621 TAILQ_FOREACH(ifma, &ifp->if_multiaddrs, ifma_link) { 5622 if (ifma->ifma_addr->sa_family != AF_LINK) 5623 continue; 5624 h = ether_crc32_le( 5625 LLADDR((struct sockaddr_dl *)ifma->ifma_addr), 5626 ETHER_ADDR_LEN) & 0xFF; 5627 hashes[(h & 0xE0) >> 5] |= 1 << (h & 0x1F); 5628 } 5629 5630 for (i = 0; i < NUM_MC_HASH_REGISTERS; i++) { 5631 REG_WR(sc, BCE_EMAC_MULTICAST_HASH0 + (i * 4), 5632 hashes[i]); 5633 } 5634 sort_mode |= BCE_RPM_SORT_USER0_MC_HSH_EN; 5635 } 5636 5637 /* Only make changes if the recive mode has actually changed. */ 5638 if (rx_mode != sc->rx_mode) { 5639 sc->rx_mode = rx_mode; 5640 REG_WR(sc, BCE_EMAC_RX_MODE, rx_mode); 5641 } 5642 5643 /* Disable and clear the exisitng sort before enabling a new sort. */ 5644 REG_WR(sc, BCE_RPM_SORT_USER0, 0x0); 5645 REG_WR(sc, BCE_RPM_SORT_USER0, sort_mode); 5646 REG_WR(sc, BCE_RPM_SORT_USER0, sort_mode | BCE_RPM_SORT_USER0_ENA); 5647 } 5648 5649 /****************************************************************************/ 5650 /* Called periodically to updates statistics from the controllers */ 5651 /* statistics block. */ 5652 /* */ 5653 /* Returns: */ 5654 /* Nothing. */ 5655 /****************************************************************************/ 5656 static void 5657 bce_stats_update(struct bce_softc *sc) 5658 { 5659 struct ifnet *ifp = &sc->arpcom.ac_if; 5660 struct statistics_block *stats = sc->stats_block; 5661 5662 ASSERT_SERIALIZED(&sc->main_serialize); 5663 5664 /* 5665 * Certain controllers don't report carrier sense errors correctly. 5666 * See errata E11_5708CA0_1165. 5667 */ 5668 if (!(BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5706) && 5669 !(BCE_CHIP_ID(sc) == BCE_CHIP_ID_5708_A0)) { 5670 IFNET_STAT_INC(ifp, oerrors, 5671 (u_long)stats->stat_Dot3StatsCarrierSenseErrors); 5672 } 5673 5674 /* 5675 * Update the sysctl statistics from the hardware statistics. 5676 */ 5677 sc->stat_IfHCInOctets = 5678 ((uint64_t)stats->stat_IfHCInOctets_hi << 32) + 5679 (uint64_t)stats->stat_IfHCInOctets_lo; 5680 5681 sc->stat_IfHCInBadOctets = 5682 ((uint64_t)stats->stat_IfHCInBadOctets_hi << 32) + 5683 (uint64_t)stats->stat_IfHCInBadOctets_lo; 5684 5685 sc->stat_IfHCOutOctets = 5686 ((uint64_t)stats->stat_IfHCOutOctets_hi << 32) + 5687 (uint64_t)stats->stat_IfHCOutOctets_lo; 5688 5689 sc->stat_IfHCOutBadOctets = 5690 ((uint64_t)stats->stat_IfHCOutBadOctets_hi << 32) + 5691 (uint64_t)stats->stat_IfHCOutBadOctets_lo; 5692 5693 sc->stat_IfHCInUcastPkts = 5694 ((uint64_t)stats->stat_IfHCInUcastPkts_hi << 32) + 5695 (uint64_t)stats->stat_IfHCInUcastPkts_lo; 5696 5697 sc->stat_IfHCInMulticastPkts = 5698 ((uint64_t)stats->stat_IfHCInMulticastPkts_hi << 32) + 5699 (uint64_t)stats->stat_IfHCInMulticastPkts_lo; 5700 5701 sc->stat_IfHCInBroadcastPkts = 5702 ((uint64_t)stats->stat_IfHCInBroadcastPkts_hi << 32) + 5703 (uint64_t)stats->stat_IfHCInBroadcastPkts_lo; 5704 5705 sc->stat_IfHCOutUcastPkts = 5706 ((uint64_t)stats->stat_IfHCOutUcastPkts_hi << 32) + 5707 (uint64_t)stats->stat_IfHCOutUcastPkts_lo; 5708 5709 sc->stat_IfHCOutMulticastPkts = 5710 ((uint64_t)stats->stat_IfHCOutMulticastPkts_hi << 32) + 5711 (uint64_t)stats->stat_IfHCOutMulticastPkts_lo; 5712 5713 sc->stat_IfHCOutBroadcastPkts = 5714 ((uint64_t)stats->stat_IfHCOutBroadcastPkts_hi << 32) + 5715 (uint64_t)stats->stat_IfHCOutBroadcastPkts_lo; 5716 5717 sc->stat_emac_tx_stat_dot3statsinternalmactransmiterrors = 5718 stats->stat_emac_tx_stat_dot3statsinternalmactransmiterrors; 5719 5720 sc->stat_Dot3StatsCarrierSenseErrors = 5721 stats->stat_Dot3StatsCarrierSenseErrors; 5722 5723 sc->stat_Dot3StatsFCSErrors = 5724 stats->stat_Dot3StatsFCSErrors; 5725 5726 sc->stat_Dot3StatsAlignmentErrors = 5727 stats->stat_Dot3StatsAlignmentErrors; 5728 5729 sc->stat_Dot3StatsSingleCollisionFrames = 5730 stats->stat_Dot3StatsSingleCollisionFrames; 5731 5732 sc->stat_Dot3StatsMultipleCollisionFrames = 5733 stats->stat_Dot3StatsMultipleCollisionFrames; 5734 5735 sc->stat_Dot3StatsDeferredTransmissions = 5736 stats->stat_Dot3StatsDeferredTransmissions; 5737 5738 sc->stat_Dot3StatsExcessiveCollisions = 5739 stats->stat_Dot3StatsExcessiveCollisions; 5740 5741 sc->stat_Dot3StatsLateCollisions = 5742 stats->stat_Dot3StatsLateCollisions; 5743 5744 sc->stat_EtherStatsCollisions = 5745 stats->stat_EtherStatsCollisions; 5746 5747 sc->stat_EtherStatsFragments = 5748 stats->stat_EtherStatsFragments; 5749 5750 sc->stat_EtherStatsJabbers = 5751 stats->stat_EtherStatsJabbers; 5752 5753 sc->stat_EtherStatsUndersizePkts = 5754 stats->stat_EtherStatsUndersizePkts; 5755 5756 sc->stat_EtherStatsOverrsizePkts = 5757 stats->stat_EtherStatsOverrsizePkts; 5758 5759 sc->stat_EtherStatsPktsRx64Octets = 5760 stats->stat_EtherStatsPktsRx64Octets; 5761 5762 sc->stat_EtherStatsPktsRx65Octetsto127Octets = 5763 stats->stat_EtherStatsPktsRx65Octetsto127Octets; 5764 5765 sc->stat_EtherStatsPktsRx128Octetsto255Octets = 5766 stats->stat_EtherStatsPktsRx128Octetsto255Octets; 5767 5768 sc->stat_EtherStatsPktsRx256Octetsto511Octets = 5769 stats->stat_EtherStatsPktsRx256Octetsto511Octets; 5770 5771 sc->stat_EtherStatsPktsRx512Octetsto1023Octets = 5772 stats->stat_EtherStatsPktsRx512Octetsto1023Octets; 5773 5774 sc->stat_EtherStatsPktsRx1024Octetsto1522Octets = 5775 stats->stat_EtherStatsPktsRx1024Octetsto1522Octets; 5776 5777 sc->stat_EtherStatsPktsRx1523Octetsto9022Octets = 5778 stats->stat_EtherStatsPktsRx1523Octetsto9022Octets; 5779 5780 sc->stat_EtherStatsPktsTx64Octets = 5781 stats->stat_EtherStatsPktsTx64Octets; 5782 5783 sc->stat_EtherStatsPktsTx65Octetsto127Octets = 5784 stats->stat_EtherStatsPktsTx65Octetsto127Octets; 5785 5786 sc->stat_EtherStatsPktsTx128Octetsto255Octets = 5787 stats->stat_EtherStatsPktsTx128Octetsto255Octets; 5788 5789 sc->stat_EtherStatsPktsTx256Octetsto511Octets = 5790 stats->stat_EtherStatsPktsTx256Octetsto511Octets; 5791 5792 sc->stat_EtherStatsPktsTx512Octetsto1023Octets = 5793 stats->stat_EtherStatsPktsTx512Octetsto1023Octets; 5794 5795 sc->stat_EtherStatsPktsTx1024Octetsto1522Octets = 5796 stats->stat_EtherStatsPktsTx1024Octetsto1522Octets; 5797 5798 sc->stat_EtherStatsPktsTx1523Octetsto9022Octets = 5799 stats->stat_EtherStatsPktsTx1523Octetsto9022Octets; 5800 5801 sc->stat_XonPauseFramesReceived = 5802 stats->stat_XonPauseFramesReceived; 5803 5804 sc->stat_XoffPauseFramesReceived = 5805 stats->stat_XoffPauseFramesReceived; 5806 5807 sc->stat_OutXonSent = 5808 stats->stat_OutXonSent; 5809 5810 sc->stat_OutXoffSent = 5811 stats->stat_OutXoffSent; 5812 5813 sc->stat_FlowControlDone = 5814 stats->stat_FlowControlDone; 5815 5816 sc->stat_MacControlFramesReceived = 5817 stats->stat_MacControlFramesReceived; 5818 5819 sc->stat_XoffStateEntered = 5820 stats->stat_XoffStateEntered; 5821 5822 sc->stat_IfInFramesL2FilterDiscards = 5823 stats->stat_IfInFramesL2FilterDiscards; 5824 5825 sc->stat_IfInRuleCheckerDiscards = 5826 stats->stat_IfInRuleCheckerDiscards; 5827 5828 sc->stat_IfInFTQDiscards = 5829 stats->stat_IfInFTQDiscards; 5830 5831 sc->stat_IfInMBUFDiscards = 5832 stats->stat_IfInMBUFDiscards; 5833 5834 sc->stat_IfInRuleCheckerP4Hit = 5835 stats->stat_IfInRuleCheckerP4Hit; 5836 5837 sc->stat_CatchupInRuleCheckerDiscards = 5838 stats->stat_CatchupInRuleCheckerDiscards; 5839 5840 sc->stat_CatchupInFTQDiscards = 5841 stats->stat_CatchupInFTQDiscards; 5842 5843 sc->stat_CatchupInMBUFDiscards = 5844 stats->stat_CatchupInMBUFDiscards; 5845 5846 sc->stat_CatchupInRuleCheckerP4Hit = 5847 stats->stat_CatchupInRuleCheckerP4Hit; 5848 5849 sc->com_no_buffers = REG_RD_IND(sc, 0x120084); 5850 5851 /* 5852 * Update the interface statistics from the 5853 * hardware statistics. 5854 */ 5855 IFNET_STAT_SET(ifp, collisions, (u_long)sc->stat_EtherStatsCollisions); 5856 5857 IFNET_STAT_SET(ifp, ierrors, (u_long)sc->stat_EtherStatsUndersizePkts + 5858 (u_long)sc->stat_EtherStatsOverrsizePkts + 5859 (u_long)sc->stat_IfInMBUFDiscards + 5860 (u_long)sc->stat_Dot3StatsAlignmentErrors + 5861 (u_long)sc->stat_Dot3StatsFCSErrors + 5862 (u_long)sc->stat_IfInRuleCheckerDiscards + 5863 (u_long)sc->stat_IfInFTQDiscards + 5864 (u_long)sc->com_no_buffers); 5865 5866 IFNET_STAT_SET(ifp, oerrors, 5867 (u_long)sc->stat_emac_tx_stat_dot3statsinternalmactransmiterrors + 5868 (u_long)sc->stat_Dot3StatsExcessiveCollisions + 5869 (u_long)sc->stat_Dot3StatsLateCollisions); 5870 } 5871 5872 /****************************************************************************/ 5873 /* Periodic function to notify the bootcode that the driver is still */ 5874 /* present. */ 5875 /* */ 5876 /* Returns: */ 5877 /* Nothing. */ 5878 /****************************************************************************/ 5879 static void 5880 bce_pulse(void *xsc) 5881 { 5882 struct bce_softc *sc = xsc; 5883 struct ifnet *ifp = &sc->arpcom.ac_if; 5884 uint32_t msg; 5885 5886 lwkt_serialize_enter(&sc->main_serialize); 5887 5888 /* Tell the firmware that the driver is still running. */ 5889 msg = (uint32_t)++sc->bce_fw_drv_pulse_wr_seq; 5890 bce_shmem_wr(sc, BCE_DRV_PULSE_MB, msg); 5891 5892 /* Update the bootcode condition. */ 5893 sc->bc_state = bce_shmem_rd(sc, BCE_BC_STATE_CONDITION); 5894 5895 /* Report whether the bootcode still knows the driver is running. */ 5896 if (!sc->bce_drv_cardiac_arrest) { 5897 if (!(sc->bc_state & BCE_CONDITION_DRV_PRESENT)) { 5898 sc->bce_drv_cardiac_arrest = 1; 5899 if_printf(ifp, "Bootcode lost the driver pulse! " 5900 "(bc_state = 0x%08X)\n", sc->bc_state); 5901 } 5902 } else { 5903 /* 5904 * Not supported by all bootcode versions. 5905 * (v5.0.11+ and v5.2.1+) Older bootcode 5906 * will require the driver to reset the 5907 * controller to clear this condition. 5908 */ 5909 if (sc->bc_state & BCE_CONDITION_DRV_PRESENT) { 5910 sc->bce_drv_cardiac_arrest = 0; 5911 if_printf(ifp, "Bootcode found the driver pulse! " 5912 "(bc_state = 0x%08X)\n", sc->bc_state); 5913 } 5914 } 5915 5916 /* Schedule the next pulse. */ 5917 callout_reset_bycpu(&sc->bce_pulse_callout, hz, bce_pulse, sc, 5918 sc->bce_timer_cpuid); 5919 5920 lwkt_serialize_exit(&sc->main_serialize); 5921 } 5922 5923 /****************************************************************************/ 5924 /* Periodic function to check whether MSI is lost */ 5925 /* */ 5926 /* Returns: */ 5927 /* Nothing. */ 5928 /****************************************************************************/ 5929 static void 5930 bce_check_msi(void *xsc) 5931 { 5932 struct bce_softc *sc = xsc; 5933 struct ifnet *ifp = &sc->arpcom.ac_if; 5934 struct status_block *sblk = sc->status_block; 5935 struct bce_tx_ring *txr = &sc->tx_rings[0]; 5936 struct bce_rx_ring *rxr = &sc->rx_rings[0]; 5937 5938 lwkt_serialize_enter(&sc->main_serialize); 5939 5940 KKASSERT(mycpuid == sc->bce_msix[0].msix_cpuid); 5941 5942 if ((ifp->if_flags & (IFF_RUNNING | IFF_NPOLLING)) != IFF_RUNNING) { 5943 lwkt_serialize_exit(&sc->main_serialize); 5944 return; 5945 } 5946 5947 if (bce_get_hw_rx_cons(rxr) != rxr->rx_cons || 5948 bce_get_hw_tx_cons(txr) != txr->tx_cons || 5949 (sblk->status_attn_bits & STATUS_ATTN_BITS_LINK_STATE) != 5950 (sblk->status_attn_bits_ack & STATUS_ATTN_BITS_LINK_STATE)) { 5951 if (sc->bce_check_rx_cons == rxr->rx_cons && 5952 sc->bce_check_tx_cons == txr->tx_cons && 5953 sc->bce_check_status_idx == rxr->last_status_idx) { 5954 uint32_t msi_ctrl; 5955 5956 if (!sc->bce_msi_maylose) { 5957 sc->bce_msi_maylose = TRUE; 5958 goto done; 5959 } 5960 5961 msi_ctrl = REG_RD(sc, BCE_PCICFG_MSI_CONTROL); 5962 if (msi_ctrl & BCE_PCICFG_MSI_CONTROL_ENABLE) { 5963 if (bootverbose) 5964 if_printf(ifp, "lost MSI\n"); 5965 5966 REG_WR(sc, BCE_PCICFG_MSI_CONTROL, 5967 msi_ctrl & ~BCE_PCICFG_MSI_CONTROL_ENABLE); 5968 REG_WR(sc, BCE_PCICFG_MSI_CONTROL, msi_ctrl); 5969 5970 bce_intr_msi(sc); 5971 } else if (bootverbose) { 5972 if_printf(ifp, "MSI may be lost\n"); 5973 } 5974 } 5975 } 5976 sc->bce_msi_maylose = FALSE; 5977 sc->bce_check_rx_cons = rxr->rx_cons; 5978 sc->bce_check_tx_cons = txr->tx_cons; 5979 sc->bce_check_status_idx = rxr->last_status_idx; 5980 5981 done: 5982 callout_reset(&sc->bce_ckmsi_callout, BCE_MSI_CKINTVL, 5983 bce_check_msi, sc); 5984 lwkt_serialize_exit(&sc->main_serialize); 5985 } 5986 5987 /****************************************************************************/ 5988 /* Periodic function to perform maintenance tasks. */ 5989 /* */ 5990 /* Returns: */ 5991 /* Nothing. */ 5992 /****************************************************************************/ 5993 static void 5994 bce_tick_serialized(struct bce_softc *sc) 5995 { 5996 struct mii_data *mii; 5997 5998 ASSERT_SERIALIZED(&sc->main_serialize); 5999 6000 /* Update the statistics from the hardware statistics block. */ 6001 bce_stats_update(sc); 6002 6003 /* Schedule the next tick. */ 6004 callout_reset_bycpu(&sc->bce_tick_callout, hz, bce_tick, sc, 6005 sc->bce_timer_cpuid); 6006 6007 /* If link is up already up then we're done. */ 6008 if (sc->bce_link) 6009 return; 6010 6011 mii = device_get_softc(sc->bce_miibus); 6012 mii_tick(mii); 6013 6014 /* Check if the link has come up. */ 6015 if ((mii->mii_media_status & IFM_ACTIVE) && 6016 IFM_SUBTYPE(mii->mii_media_active) != IFM_NONE) { 6017 int i; 6018 6019 sc->bce_link++; 6020 /* Now that link is up, handle any outstanding TX traffic. */ 6021 for (i = 0; i < sc->tx_ring_cnt; ++i) 6022 ifsq_devstart_sched(sc->tx_rings[i].ifsq); 6023 } 6024 } 6025 6026 static void 6027 bce_tick(void *xsc) 6028 { 6029 struct bce_softc *sc = xsc; 6030 6031 lwkt_serialize_enter(&sc->main_serialize); 6032 bce_tick_serialized(sc); 6033 lwkt_serialize_exit(&sc->main_serialize); 6034 } 6035 6036 /****************************************************************************/ 6037 /* Adds any sysctl parameters for tuning or debugging purposes. */ 6038 /* */ 6039 /* Returns: */ 6040 /* 0 for success, positive value for failure. */ 6041 /****************************************************************************/ 6042 static void 6043 bce_add_sysctls(struct bce_softc *sc) 6044 { 6045 struct sysctl_ctx_list *ctx; 6046 struct sysctl_oid_list *children; 6047 #if defined(BCE_TSS_DEBUG) || defined(BCE_RSS_DEBUG) 6048 char node[32]; 6049 int i; 6050 #endif 6051 6052 ctx = device_get_sysctl_ctx(sc->bce_dev); 6053 children = SYSCTL_CHILDREN(device_get_sysctl_tree(sc->bce_dev)); 6054 6055 SYSCTL_ADD_PROC(ctx, children, OID_AUTO, "tx_bds_int", 6056 CTLTYPE_INT | CTLFLAG_RW, 6057 sc, 0, bce_sysctl_tx_bds_int, "I", 6058 "Send max coalesced BD count during interrupt"); 6059 SYSCTL_ADD_PROC(ctx, children, OID_AUTO, "tx_bds", 6060 CTLTYPE_INT | CTLFLAG_RW, 6061 sc, 0, bce_sysctl_tx_bds, "I", 6062 "Send max coalesced BD count"); 6063 SYSCTL_ADD_PROC(ctx, children, OID_AUTO, "tx_ticks_int", 6064 CTLTYPE_INT | CTLFLAG_RW, 6065 sc, 0, bce_sysctl_tx_ticks_int, "I", 6066 "Send coalescing ticks during interrupt"); 6067 SYSCTL_ADD_PROC(ctx, children, OID_AUTO, "tx_ticks", 6068 CTLTYPE_INT | CTLFLAG_RW, 6069 sc, 0, bce_sysctl_tx_ticks, "I", 6070 "Send coalescing ticks"); 6071 6072 SYSCTL_ADD_PROC(ctx, children, OID_AUTO, "rx_bds_int", 6073 CTLTYPE_INT | CTLFLAG_RW, 6074 sc, 0, bce_sysctl_rx_bds_int, "I", 6075 "Receive max coalesced BD count during interrupt"); 6076 SYSCTL_ADD_PROC(ctx, children, OID_AUTO, "rx_bds", 6077 CTLTYPE_INT | CTLFLAG_RW, 6078 sc, 0, bce_sysctl_rx_bds, "I", 6079 "Receive max coalesced BD count"); 6080 SYSCTL_ADD_PROC(ctx, children, OID_AUTO, "rx_ticks_int", 6081 CTLTYPE_INT | CTLFLAG_RW, 6082 sc, 0, bce_sysctl_rx_ticks_int, "I", 6083 "Receive coalescing ticks during interrupt"); 6084 SYSCTL_ADD_PROC(ctx, children, OID_AUTO, "rx_ticks", 6085 CTLTYPE_INT | CTLFLAG_RW, 6086 sc, 0, bce_sysctl_rx_ticks, "I", 6087 "Receive coalescing ticks"); 6088 6089 SYSCTL_ADD_INT(ctx, children, OID_AUTO, "rx_rings", 6090 CTLFLAG_RD, &sc->rx_ring_cnt, 0, "# of RX rings"); 6091 SYSCTL_ADD_INT(ctx, children, OID_AUTO, "rx_pages", 6092 CTLFLAG_RD, &sc->rx_rings[0].rx_pages, 0, "# of RX pages"); 6093 6094 SYSCTL_ADD_INT(ctx, children, OID_AUTO, "tx_rings", 6095 CTLFLAG_RD, &sc->tx_ring_cnt, 0, "# of TX rings"); 6096 SYSCTL_ADD_INT(ctx, children, OID_AUTO, "tx_pages", 6097 CTLFLAG_RD, &sc->tx_rings[0].tx_pages, 0, "# of TX pages"); 6098 6099 SYSCTL_ADD_INT(ctx, children, OID_AUTO, "tx_wreg", 6100 CTLFLAG_RW, &sc->tx_rings[0].tx_wreg, 0, 6101 "# segments before write to hardware registers"); 6102 6103 #ifdef IFPOLL_ENABLE 6104 SYSCTL_ADD_PROC(ctx, children, OID_AUTO, "npoll_offset", 6105 CTLTYPE_INT|CTLFLAG_RW, sc, 0, bce_sysctl_npoll_offset, 6106 "I", "NPOLLING cpu offset"); 6107 #endif 6108 6109 #ifdef BCE_RSS_DEBUG 6110 SYSCTL_ADD_INT(ctx, children, OID_AUTO, "rss_debug", 6111 CTLFLAG_RW, &sc->rss_debug, 0, "RSS debug level"); 6112 for (i = 0; i < sc->rx_ring_cnt; ++i) { 6113 ksnprintf(node, sizeof(node), "rx%d_pkt", i); 6114 SYSCTL_ADD_ULONG(ctx, children, OID_AUTO, node, 6115 CTLFLAG_RW, &sc->rx_rings[i].rx_pkts, 6116 "RXed packets"); 6117 } 6118 #endif 6119 6120 #ifdef BCE_TSS_DEBUG 6121 for (i = 0; i < sc->tx_ring_cnt; ++i) { 6122 ksnprintf(node, sizeof(node), "tx%d_pkt", i); 6123 SYSCTL_ADD_ULONG(ctx, children, OID_AUTO, node, 6124 CTLFLAG_RW, &sc->tx_rings[i].tx_pkts, 6125 "TXed packets"); 6126 } 6127 #endif 6128 6129 SYSCTL_ADD_ULONG(ctx, children, OID_AUTO, 6130 "stat_IfHCInOctets", 6131 CTLFLAG_RD, &sc->stat_IfHCInOctets, 6132 "Bytes received"); 6133 6134 SYSCTL_ADD_ULONG(ctx, children, OID_AUTO, 6135 "stat_IfHCInBadOctets", 6136 CTLFLAG_RD, &sc->stat_IfHCInBadOctets, 6137 "Bad bytes received"); 6138 6139 SYSCTL_ADD_ULONG(ctx, children, OID_AUTO, 6140 "stat_IfHCOutOctets", 6141 CTLFLAG_RD, &sc->stat_IfHCOutOctets, 6142 "Bytes sent"); 6143 6144 SYSCTL_ADD_ULONG(ctx, children, OID_AUTO, 6145 "stat_IfHCOutBadOctets", 6146 CTLFLAG_RD, &sc->stat_IfHCOutBadOctets, 6147 "Bad bytes sent"); 6148 6149 SYSCTL_ADD_ULONG(ctx, children, OID_AUTO, 6150 "stat_IfHCInUcastPkts", 6151 CTLFLAG_RD, &sc->stat_IfHCInUcastPkts, 6152 "Unicast packets received"); 6153 6154 SYSCTL_ADD_ULONG(ctx, children, OID_AUTO, 6155 "stat_IfHCInMulticastPkts", 6156 CTLFLAG_RD, &sc->stat_IfHCInMulticastPkts, 6157 "Multicast packets received"); 6158 6159 SYSCTL_ADD_ULONG(ctx, children, OID_AUTO, 6160 "stat_IfHCInBroadcastPkts", 6161 CTLFLAG_RD, &sc->stat_IfHCInBroadcastPkts, 6162 "Broadcast packets received"); 6163 6164 SYSCTL_ADD_ULONG(ctx, children, OID_AUTO, 6165 "stat_IfHCOutUcastPkts", 6166 CTLFLAG_RD, &sc->stat_IfHCOutUcastPkts, 6167 "Unicast packets sent"); 6168 6169 SYSCTL_ADD_ULONG(ctx, children, OID_AUTO, 6170 "stat_IfHCOutMulticastPkts", 6171 CTLFLAG_RD, &sc->stat_IfHCOutMulticastPkts, 6172 "Multicast packets sent"); 6173 6174 SYSCTL_ADD_ULONG(ctx, children, OID_AUTO, 6175 "stat_IfHCOutBroadcastPkts", 6176 CTLFLAG_RD, &sc->stat_IfHCOutBroadcastPkts, 6177 "Broadcast packets sent"); 6178 6179 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6180 "stat_emac_tx_stat_dot3statsinternalmactransmiterrors", 6181 CTLFLAG_RD, &sc->stat_emac_tx_stat_dot3statsinternalmactransmiterrors, 6182 0, "Internal MAC transmit errors"); 6183 6184 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6185 "stat_Dot3StatsCarrierSenseErrors", 6186 CTLFLAG_RD, &sc->stat_Dot3StatsCarrierSenseErrors, 6187 0, "Carrier sense errors"); 6188 6189 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6190 "stat_Dot3StatsFCSErrors", 6191 CTLFLAG_RD, &sc->stat_Dot3StatsFCSErrors, 6192 0, "Frame check sequence errors"); 6193 6194 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6195 "stat_Dot3StatsAlignmentErrors", 6196 CTLFLAG_RD, &sc->stat_Dot3StatsAlignmentErrors, 6197 0, "Alignment errors"); 6198 6199 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6200 "stat_Dot3StatsSingleCollisionFrames", 6201 CTLFLAG_RD, &sc->stat_Dot3StatsSingleCollisionFrames, 6202 0, "Single Collision Frames"); 6203 6204 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6205 "stat_Dot3StatsMultipleCollisionFrames", 6206 CTLFLAG_RD, &sc->stat_Dot3StatsMultipleCollisionFrames, 6207 0, "Multiple Collision Frames"); 6208 6209 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6210 "stat_Dot3StatsDeferredTransmissions", 6211 CTLFLAG_RD, &sc->stat_Dot3StatsDeferredTransmissions, 6212 0, "Deferred Transmissions"); 6213 6214 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6215 "stat_Dot3StatsExcessiveCollisions", 6216 CTLFLAG_RD, &sc->stat_Dot3StatsExcessiveCollisions, 6217 0, "Excessive Collisions"); 6218 6219 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6220 "stat_Dot3StatsLateCollisions", 6221 CTLFLAG_RD, &sc->stat_Dot3StatsLateCollisions, 6222 0, "Late Collisions"); 6223 6224 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6225 "stat_EtherStatsCollisions", 6226 CTLFLAG_RD, &sc->stat_EtherStatsCollisions, 6227 0, "Collisions"); 6228 6229 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6230 "stat_EtherStatsFragments", 6231 CTLFLAG_RD, &sc->stat_EtherStatsFragments, 6232 0, "Fragments"); 6233 6234 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6235 "stat_EtherStatsJabbers", 6236 CTLFLAG_RD, &sc->stat_EtherStatsJabbers, 6237 0, "Jabbers"); 6238 6239 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6240 "stat_EtherStatsUndersizePkts", 6241 CTLFLAG_RD, &sc->stat_EtherStatsUndersizePkts, 6242 0, "Undersize packets"); 6243 6244 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6245 "stat_EtherStatsOverrsizePkts", 6246 CTLFLAG_RD, &sc->stat_EtherStatsOverrsizePkts, 6247 0, "stat_EtherStatsOverrsizePkts"); 6248 6249 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6250 "stat_EtherStatsPktsRx64Octets", 6251 CTLFLAG_RD, &sc->stat_EtherStatsPktsRx64Octets, 6252 0, "Bytes received in 64 byte packets"); 6253 6254 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6255 "stat_EtherStatsPktsRx65Octetsto127Octets", 6256 CTLFLAG_RD, &sc->stat_EtherStatsPktsRx65Octetsto127Octets, 6257 0, "Bytes received in 65 to 127 byte packets"); 6258 6259 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6260 "stat_EtherStatsPktsRx128Octetsto255Octets", 6261 CTLFLAG_RD, &sc->stat_EtherStatsPktsRx128Octetsto255Octets, 6262 0, "Bytes received in 128 to 255 byte packets"); 6263 6264 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6265 "stat_EtherStatsPktsRx256Octetsto511Octets", 6266 CTLFLAG_RD, &sc->stat_EtherStatsPktsRx256Octetsto511Octets, 6267 0, "Bytes received in 256 to 511 byte packets"); 6268 6269 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6270 "stat_EtherStatsPktsRx512Octetsto1023Octets", 6271 CTLFLAG_RD, &sc->stat_EtherStatsPktsRx512Octetsto1023Octets, 6272 0, "Bytes received in 512 to 1023 byte packets"); 6273 6274 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6275 "stat_EtherStatsPktsRx1024Octetsto1522Octets", 6276 CTLFLAG_RD, &sc->stat_EtherStatsPktsRx1024Octetsto1522Octets, 6277 0, "Bytes received in 1024 t0 1522 byte packets"); 6278 6279 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6280 "stat_EtherStatsPktsRx1523Octetsto9022Octets", 6281 CTLFLAG_RD, &sc->stat_EtherStatsPktsRx1523Octetsto9022Octets, 6282 0, "Bytes received in 1523 to 9022 byte packets"); 6283 6284 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6285 "stat_EtherStatsPktsTx64Octets", 6286 CTLFLAG_RD, &sc->stat_EtherStatsPktsTx64Octets, 6287 0, "Bytes sent in 64 byte packets"); 6288 6289 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6290 "stat_EtherStatsPktsTx65Octetsto127Octets", 6291 CTLFLAG_RD, &sc->stat_EtherStatsPktsTx65Octetsto127Octets, 6292 0, "Bytes sent in 65 to 127 byte packets"); 6293 6294 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6295 "stat_EtherStatsPktsTx128Octetsto255Octets", 6296 CTLFLAG_RD, &sc->stat_EtherStatsPktsTx128Octetsto255Octets, 6297 0, "Bytes sent in 128 to 255 byte packets"); 6298 6299 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6300 "stat_EtherStatsPktsTx256Octetsto511Octets", 6301 CTLFLAG_RD, &sc->stat_EtherStatsPktsTx256Octetsto511Octets, 6302 0, "Bytes sent in 256 to 511 byte packets"); 6303 6304 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6305 "stat_EtherStatsPktsTx512Octetsto1023Octets", 6306 CTLFLAG_RD, &sc->stat_EtherStatsPktsTx512Octetsto1023Octets, 6307 0, "Bytes sent in 512 to 1023 byte packets"); 6308 6309 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6310 "stat_EtherStatsPktsTx1024Octetsto1522Octets", 6311 CTLFLAG_RD, &sc->stat_EtherStatsPktsTx1024Octetsto1522Octets, 6312 0, "Bytes sent in 1024 to 1522 byte packets"); 6313 6314 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6315 "stat_EtherStatsPktsTx1523Octetsto9022Octets", 6316 CTLFLAG_RD, &sc->stat_EtherStatsPktsTx1523Octetsto9022Octets, 6317 0, "Bytes sent in 1523 to 9022 byte packets"); 6318 6319 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6320 "stat_XonPauseFramesReceived", 6321 CTLFLAG_RD, &sc->stat_XonPauseFramesReceived, 6322 0, "XON pause frames receved"); 6323 6324 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6325 "stat_XoffPauseFramesReceived", 6326 CTLFLAG_RD, &sc->stat_XoffPauseFramesReceived, 6327 0, "XOFF pause frames received"); 6328 6329 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6330 "stat_OutXonSent", 6331 CTLFLAG_RD, &sc->stat_OutXonSent, 6332 0, "XON pause frames sent"); 6333 6334 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6335 "stat_OutXoffSent", 6336 CTLFLAG_RD, &sc->stat_OutXoffSent, 6337 0, "XOFF pause frames sent"); 6338 6339 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6340 "stat_FlowControlDone", 6341 CTLFLAG_RD, &sc->stat_FlowControlDone, 6342 0, "Flow control done"); 6343 6344 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6345 "stat_MacControlFramesReceived", 6346 CTLFLAG_RD, &sc->stat_MacControlFramesReceived, 6347 0, "MAC control frames received"); 6348 6349 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6350 "stat_XoffStateEntered", 6351 CTLFLAG_RD, &sc->stat_XoffStateEntered, 6352 0, "XOFF state entered"); 6353 6354 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6355 "stat_IfInFramesL2FilterDiscards", 6356 CTLFLAG_RD, &sc->stat_IfInFramesL2FilterDiscards, 6357 0, "Received L2 packets discarded"); 6358 6359 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6360 "stat_IfInRuleCheckerDiscards", 6361 CTLFLAG_RD, &sc->stat_IfInRuleCheckerDiscards, 6362 0, "Received packets discarded by rule"); 6363 6364 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6365 "stat_IfInFTQDiscards", 6366 CTLFLAG_RD, &sc->stat_IfInFTQDiscards, 6367 0, "Received packet FTQ discards"); 6368 6369 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6370 "stat_IfInMBUFDiscards", 6371 CTLFLAG_RD, &sc->stat_IfInMBUFDiscards, 6372 0, "Received packets discarded due to lack of controller buffer memory"); 6373 6374 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6375 "stat_IfInRuleCheckerP4Hit", 6376 CTLFLAG_RD, &sc->stat_IfInRuleCheckerP4Hit, 6377 0, "Received packets rule checker hits"); 6378 6379 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6380 "stat_CatchupInRuleCheckerDiscards", 6381 CTLFLAG_RD, &sc->stat_CatchupInRuleCheckerDiscards, 6382 0, "Received packets discarded in Catchup path"); 6383 6384 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6385 "stat_CatchupInFTQDiscards", 6386 CTLFLAG_RD, &sc->stat_CatchupInFTQDiscards, 6387 0, "Received packets discarded in FTQ in Catchup path"); 6388 6389 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6390 "stat_CatchupInMBUFDiscards", 6391 CTLFLAG_RD, &sc->stat_CatchupInMBUFDiscards, 6392 0, "Received packets discarded in controller buffer memory in Catchup path"); 6393 6394 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6395 "stat_CatchupInRuleCheckerP4Hit", 6396 CTLFLAG_RD, &sc->stat_CatchupInRuleCheckerP4Hit, 6397 0, "Received packets rule checker hits in Catchup path"); 6398 6399 SYSCTL_ADD_UINT(ctx, children, OID_AUTO, 6400 "com_no_buffers", 6401 CTLFLAG_RD, &sc->com_no_buffers, 6402 0, "Valid packets received but no RX buffers available"); 6403 } 6404 6405 static int 6406 bce_sysctl_tx_bds_int(SYSCTL_HANDLER_ARGS) 6407 { 6408 struct bce_softc *sc = arg1; 6409 6410 return bce_sysctl_coal_change(oidp, arg1, arg2, req, 6411 &sc->bce_tx_quick_cons_trip_int, 6412 BCE_COALMASK_TX_BDS_INT); 6413 } 6414 6415 static int 6416 bce_sysctl_tx_bds(SYSCTL_HANDLER_ARGS) 6417 { 6418 struct bce_softc *sc = arg1; 6419 6420 return bce_sysctl_coal_change(oidp, arg1, arg2, req, 6421 &sc->bce_tx_quick_cons_trip, 6422 BCE_COALMASK_TX_BDS); 6423 } 6424 6425 static int 6426 bce_sysctl_tx_ticks_int(SYSCTL_HANDLER_ARGS) 6427 { 6428 struct bce_softc *sc = arg1; 6429 6430 return bce_sysctl_coal_change(oidp, arg1, arg2, req, 6431 &sc->bce_tx_ticks_int, 6432 BCE_COALMASK_TX_TICKS_INT); 6433 } 6434 6435 static int 6436 bce_sysctl_tx_ticks(SYSCTL_HANDLER_ARGS) 6437 { 6438 struct bce_softc *sc = arg1; 6439 6440 return bce_sysctl_coal_change(oidp, arg1, arg2, req, 6441 &sc->bce_tx_ticks, 6442 BCE_COALMASK_TX_TICKS); 6443 } 6444 6445 static int 6446 bce_sysctl_rx_bds_int(SYSCTL_HANDLER_ARGS) 6447 { 6448 struct bce_softc *sc = arg1; 6449 6450 return bce_sysctl_coal_change(oidp, arg1, arg2, req, 6451 &sc->bce_rx_quick_cons_trip_int, 6452 BCE_COALMASK_RX_BDS_INT); 6453 } 6454 6455 static int 6456 bce_sysctl_rx_bds(SYSCTL_HANDLER_ARGS) 6457 { 6458 struct bce_softc *sc = arg1; 6459 6460 return bce_sysctl_coal_change(oidp, arg1, arg2, req, 6461 &sc->bce_rx_quick_cons_trip, 6462 BCE_COALMASK_RX_BDS); 6463 } 6464 6465 static int 6466 bce_sysctl_rx_ticks_int(SYSCTL_HANDLER_ARGS) 6467 { 6468 struct bce_softc *sc = arg1; 6469 6470 return bce_sysctl_coal_change(oidp, arg1, arg2, req, 6471 &sc->bce_rx_ticks_int, 6472 BCE_COALMASK_RX_TICKS_INT); 6473 } 6474 6475 static int 6476 bce_sysctl_rx_ticks(SYSCTL_HANDLER_ARGS) 6477 { 6478 struct bce_softc *sc = arg1; 6479 6480 return bce_sysctl_coal_change(oidp, arg1, arg2, req, 6481 &sc->bce_rx_ticks, 6482 BCE_COALMASK_RX_TICKS); 6483 } 6484 6485 static int 6486 bce_sysctl_coal_change(SYSCTL_HANDLER_ARGS, uint32_t *coal, 6487 uint32_t coalchg_mask) 6488 { 6489 struct bce_softc *sc = arg1; 6490 struct ifnet *ifp = &sc->arpcom.ac_if; 6491 int error = 0, v; 6492 6493 ifnet_serialize_all(ifp); 6494 6495 v = *coal; 6496 error = sysctl_handle_int(oidp, &v, 0, req); 6497 if (!error && req->newptr != NULL) { 6498 if (v < 0) { 6499 error = EINVAL; 6500 } else { 6501 *coal = v; 6502 sc->bce_coalchg_mask |= coalchg_mask; 6503 6504 /* Commit changes */ 6505 bce_coal_change(sc); 6506 } 6507 } 6508 6509 ifnet_deserialize_all(ifp); 6510 return error; 6511 } 6512 6513 static void 6514 bce_coal_change(struct bce_softc *sc) 6515 { 6516 struct ifnet *ifp = &sc->arpcom.ac_if; 6517 int i; 6518 6519 ASSERT_SERIALIZED(&sc->main_serialize); 6520 6521 if ((ifp->if_flags & IFF_RUNNING) == 0) { 6522 sc->bce_coalchg_mask = 0; 6523 return; 6524 } 6525 6526 if (sc->bce_coalchg_mask & 6527 (BCE_COALMASK_TX_BDS | BCE_COALMASK_TX_BDS_INT)) { 6528 REG_WR(sc, BCE_HC_TX_QUICK_CONS_TRIP, 6529 (sc->bce_tx_quick_cons_trip_int << 16) | 6530 sc->bce_tx_quick_cons_trip); 6531 for (i = 1; i < sc->rx_ring_cnt; ++i) { 6532 uint32_t base; 6533 6534 base = ((i - 1) * BCE_HC_SB_CONFIG_SIZE) + 6535 BCE_HC_SB_CONFIG_1; 6536 REG_WR(sc, base + BCE_HC_TX_QUICK_CONS_TRIP_OFF, 6537 (sc->bce_tx_quick_cons_trip_int << 16) | 6538 sc->bce_tx_quick_cons_trip); 6539 } 6540 if (bootverbose) { 6541 if_printf(ifp, "tx_bds %u, tx_bds_int %u\n", 6542 sc->bce_tx_quick_cons_trip, 6543 sc->bce_tx_quick_cons_trip_int); 6544 } 6545 } 6546 6547 if (sc->bce_coalchg_mask & 6548 (BCE_COALMASK_TX_TICKS | BCE_COALMASK_TX_TICKS_INT)) { 6549 REG_WR(sc, BCE_HC_TX_TICKS, 6550 (sc->bce_tx_ticks_int << 16) | sc->bce_tx_ticks); 6551 for (i = 1; i < sc->rx_ring_cnt; ++i) { 6552 uint32_t base; 6553 6554 base = ((i - 1) * BCE_HC_SB_CONFIG_SIZE) + 6555 BCE_HC_SB_CONFIG_1; 6556 REG_WR(sc, base + BCE_HC_TX_TICKS_OFF, 6557 (sc->bce_tx_ticks_int << 16) | sc->bce_tx_ticks); 6558 } 6559 if (bootverbose) { 6560 if_printf(ifp, "tx_ticks %u, tx_ticks_int %u\n", 6561 sc->bce_tx_ticks, sc->bce_tx_ticks_int); 6562 } 6563 } 6564 6565 if (sc->bce_coalchg_mask & 6566 (BCE_COALMASK_RX_BDS | BCE_COALMASK_RX_BDS_INT)) { 6567 REG_WR(sc, BCE_HC_RX_QUICK_CONS_TRIP, 6568 (sc->bce_rx_quick_cons_trip_int << 16) | 6569 sc->bce_rx_quick_cons_trip); 6570 for (i = 1; i < sc->rx_ring_cnt; ++i) { 6571 uint32_t base; 6572 6573 base = ((i - 1) * BCE_HC_SB_CONFIG_SIZE) + 6574 BCE_HC_SB_CONFIG_1; 6575 REG_WR(sc, base + BCE_HC_RX_QUICK_CONS_TRIP_OFF, 6576 (sc->bce_rx_quick_cons_trip_int << 16) | 6577 sc->bce_rx_quick_cons_trip); 6578 } 6579 if (bootverbose) { 6580 if_printf(ifp, "rx_bds %u, rx_bds_int %u\n", 6581 sc->bce_rx_quick_cons_trip, 6582 sc->bce_rx_quick_cons_trip_int); 6583 } 6584 } 6585 6586 if (sc->bce_coalchg_mask & 6587 (BCE_COALMASK_RX_TICKS | BCE_COALMASK_RX_TICKS_INT)) { 6588 REG_WR(sc, BCE_HC_RX_TICKS, 6589 (sc->bce_rx_ticks_int << 16) | sc->bce_rx_ticks); 6590 for (i = 1; i < sc->rx_ring_cnt; ++i) { 6591 uint32_t base; 6592 6593 base = ((i - 1) * BCE_HC_SB_CONFIG_SIZE) + 6594 BCE_HC_SB_CONFIG_1; 6595 REG_WR(sc, base + BCE_HC_RX_TICKS_OFF, 6596 (sc->bce_rx_ticks_int << 16) | sc->bce_rx_ticks); 6597 } 6598 if (bootverbose) { 6599 if_printf(ifp, "rx_ticks %u, rx_ticks_int %u\n", 6600 sc->bce_rx_ticks, sc->bce_rx_ticks_int); 6601 } 6602 } 6603 6604 sc->bce_coalchg_mask = 0; 6605 } 6606 6607 static int 6608 bce_tso_setup(struct bce_tx_ring *txr, struct mbuf **mp, 6609 uint16_t *flags0, uint16_t *mss0) 6610 { 6611 struct mbuf *m; 6612 uint16_t flags; 6613 int thoff, iphlen, hoff; 6614 6615 m = *mp; 6616 KASSERT(M_WRITABLE(m), ("TSO mbuf not writable")); 6617 6618 hoff = m->m_pkthdr.csum_lhlen; 6619 iphlen = m->m_pkthdr.csum_iphlen; 6620 thoff = m->m_pkthdr.csum_thlen; 6621 6622 KASSERT(hoff >= sizeof(struct ether_header), 6623 ("invalid ether header len %d", hoff)); 6624 KASSERT(iphlen >= sizeof(struct ip), 6625 ("invalid ip header len %d", iphlen)); 6626 KASSERT(thoff >= sizeof(struct tcphdr), 6627 ("invalid tcp header len %d", thoff)); 6628 6629 if (__predict_false(m->m_len < hoff + iphlen + thoff)) { 6630 m = m_pullup(m, hoff + iphlen + thoff); 6631 if (m == NULL) { 6632 *mp = NULL; 6633 return ENOBUFS; 6634 } 6635 *mp = m; 6636 } 6637 6638 /* Set the LSO flag in the TX BD */ 6639 flags = TX_BD_FLAGS_SW_LSO; 6640 6641 /* Set the length of IP + TCP options (in 32 bit words) */ 6642 flags |= (((iphlen + thoff - 6643 sizeof(struct ip) - sizeof(struct tcphdr)) >> 2) << 8); 6644 6645 *mss0 = htole16(m->m_pkthdr.tso_segsz); 6646 *flags0 = flags; 6647 6648 return 0; 6649 } 6650 6651 static void 6652 bce_setup_serialize(struct bce_softc *sc) 6653 { 6654 int i, j; 6655 6656 /* 6657 * Allocate serializer array 6658 */ 6659 6660 /* Main + TX + RX */ 6661 sc->serialize_cnt = 1 + sc->tx_ring_cnt + sc->rx_ring_cnt; 6662 6663 sc->serializes = 6664 kmalloc(sc->serialize_cnt * sizeof(struct lwkt_serialize *), 6665 M_DEVBUF, M_WAITOK | M_ZERO); 6666 6667 /* 6668 * Setup serializers 6669 * 6670 * NOTE: Order is critical 6671 */ 6672 6673 i = 0; 6674 6675 KKASSERT(i < sc->serialize_cnt); 6676 sc->serializes[i++] = &sc->main_serialize; 6677 6678 for (j = 0; j < sc->rx_ring_cnt; ++j) { 6679 KKASSERT(i < sc->serialize_cnt); 6680 sc->serializes[i++] = &sc->rx_rings[j].rx_serialize; 6681 } 6682 6683 for (j = 0; j < sc->tx_ring_cnt; ++j) { 6684 KKASSERT(i < sc->serialize_cnt); 6685 sc->serializes[i++] = &sc->tx_rings[j].tx_serialize; 6686 } 6687 6688 KKASSERT(i == sc->serialize_cnt); 6689 } 6690 6691 static void 6692 bce_serialize(struct ifnet *ifp, enum ifnet_serialize slz) 6693 { 6694 struct bce_softc *sc = ifp->if_softc; 6695 6696 ifnet_serialize_array_enter(sc->serializes, sc->serialize_cnt, slz); 6697 } 6698 6699 static void 6700 bce_deserialize(struct ifnet *ifp, enum ifnet_serialize slz) 6701 { 6702 struct bce_softc *sc = ifp->if_softc; 6703 6704 ifnet_serialize_array_exit(sc->serializes, sc->serialize_cnt, slz); 6705 } 6706 6707 static int 6708 bce_tryserialize(struct ifnet *ifp, enum ifnet_serialize slz) 6709 { 6710 struct bce_softc *sc = ifp->if_softc; 6711 6712 return ifnet_serialize_array_try(sc->serializes, sc->serialize_cnt, 6713 slz); 6714 } 6715 6716 #ifdef INVARIANTS 6717 6718 static void 6719 bce_serialize_assert(struct ifnet *ifp, enum ifnet_serialize slz, 6720 boolean_t serialized) 6721 { 6722 struct bce_softc *sc = ifp->if_softc; 6723 6724 ifnet_serialize_array_assert(sc->serializes, sc->serialize_cnt, 6725 slz, serialized); 6726 } 6727 6728 #endif /* INVARIANTS */ 6729 6730 static void 6731 bce_serialize_skipmain(struct bce_softc *sc) 6732 { 6733 lwkt_serialize_array_enter(sc->serializes, sc->serialize_cnt, 1); 6734 } 6735 6736 static void 6737 bce_deserialize_skipmain(struct bce_softc *sc) 6738 { 6739 lwkt_serialize_array_exit(sc->serializes, sc->serialize_cnt, 1); 6740 } 6741 6742 #ifdef IFPOLL_ENABLE 6743 6744 static int 6745 bce_sysctl_npoll_offset(SYSCTL_HANDLER_ARGS) 6746 { 6747 struct bce_softc *sc = (void *)arg1; 6748 struct ifnet *ifp = &sc->arpcom.ac_if; 6749 int error, off; 6750 6751 off = sc->npoll_ofs; 6752 error = sysctl_handle_int(oidp, &off, 0, req); 6753 if (error || req->newptr == NULL) 6754 return error; 6755 if (off < 0) 6756 return EINVAL; 6757 6758 ifnet_serialize_all(ifp); 6759 if (off >= ncpus2 || off % sc->rx_ring_cnt2 != 0) { 6760 error = EINVAL; 6761 } else { 6762 error = 0; 6763 sc->npoll_ofs = off; 6764 } 6765 ifnet_deserialize_all(ifp); 6766 6767 return error; 6768 } 6769 6770 #endif /* IFPOLL_ENABLE */ 6771 6772 static void 6773 bce_set_timer_cpuid(struct bce_softc *sc, boolean_t polling) 6774 { 6775 if (polling) 6776 sc->bce_timer_cpuid = 0; /* XXX */ 6777 else 6778 sc->bce_timer_cpuid = sc->bce_msix[0].msix_cpuid; 6779 } 6780 6781 static int 6782 bce_alloc_intr(struct bce_softc *sc) 6783 { 6784 u_int irq_flags; 6785 6786 bce_try_alloc_msix(sc); 6787 if (sc->bce_irq_type == PCI_INTR_TYPE_MSIX) 6788 return 0; 6789 6790 sc->bce_irq_type = pci_alloc_1intr(sc->bce_dev, bce_msi_enable, 6791 &sc->bce_irq_rid, &irq_flags); 6792 6793 sc->bce_res_irq = bus_alloc_resource_any(sc->bce_dev, SYS_RES_IRQ, 6794 &sc->bce_irq_rid, irq_flags); 6795 if (sc->bce_res_irq == NULL) { 6796 device_printf(sc->bce_dev, "PCI map interrupt failed\n"); 6797 return ENXIO; 6798 } 6799 sc->bce_msix[0].msix_cpuid = rman_get_cpuid(sc->bce_res_irq); 6800 sc->bce_msix[0].msix_serialize = &sc->main_serialize; 6801 6802 return 0; 6803 } 6804 6805 static void 6806 bce_try_alloc_msix(struct bce_softc *sc) 6807 { 6808 struct bce_msix_data *msix; 6809 int offset, i, error; 6810 boolean_t setup = FALSE; 6811 6812 if (sc->rx_ring_cnt == 1) 6813 return; 6814 6815 if (sc->rx_ring_cnt2 == ncpus2) { 6816 offset = 0; 6817 } else { 6818 int offset_def = 6819 (sc->rx_ring_cnt2 * device_get_unit(sc->bce_dev)) % ncpus2; 6820 6821 offset = device_getenv_int(sc->bce_dev, 6822 "msix.offset", offset_def); 6823 if (offset >= ncpus2 || offset % sc->rx_ring_cnt2 != 0) { 6824 device_printf(sc->bce_dev, 6825 "invalid msix.offset %d, use %d\n", 6826 offset, offset_def); 6827 offset = offset_def; 6828 } 6829 } 6830 6831 msix = &sc->bce_msix[0]; 6832 msix->msix_serialize = &sc->main_serialize; 6833 msix->msix_func = bce_intr_msi_oneshot; 6834 msix->msix_arg = sc; 6835 KKASSERT(offset < ncpus2); 6836 msix->msix_cpuid = offset; 6837 ksnprintf(msix->msix_desc, sizeof(msix->msix_desc), "%s combo", 6838 device_get_nameunit(sc->bce_dev)); 6839 6840 for (i = 1; i < sc->rx_ring_cnt; ++i) { 6841 struct bce_rx_ring *rxr = &sc->rx_rings[i]; 6842 6843 msix = &sc->bce_msix[i]; 6844 6845 msix->msix_serialize = &rxr->rx_serialize; 6846 msix->msix_arg = rxr; 6847 msix->msix_cpuid = offset + (i % sc->rx_ring_cnt2); 6848 KKASSERT(msix->msix_cpuid < ncpus2); 6849 6850 if (i < sc->tx_ring_cnt) { 6851 msix->msix_func = bce_intr_msix_rxtx; 6852 ksnprintf(msix->msix_desc, sizeof(msix->msix_desc), 6853 "%s rxtx%d", device_get_nameunit(sc->bce_dev), i); 6854 } else { 6855 msix->msix_func = bce_intr_msix_rx; 6856 ksnprintf(msix->msix_desc, sizeof(msix->msix_desc), 6857 "%s rx%d", device_get_nameunit(sc->bce_dev), i); 6858 } 6859 } 6860 6861 /* 6862 * Setup MSI-X table 6863 */ 6864 bce_setup_msix_table(sc); 6865 REG_WR(sc, BCE_PCI_MSIX_CONTROL, BCE_MSIX_MAX - 1); 6866 REG_WR(sc, BCE_PCI_MSIX_TBL_OFF_BIR, BCE_PCI_GRC_WINDOW2_BASE); 6867 REG_WR(sc, BCE_PCI_MSIX_PBA_OFF_BIT, BCE_PCI_GRC_WINDOW3_BASE); 6868 /* Flush */ 6869 REG_RD(sc, BCE_PCI_MSIX_CONTROL); 6870 6871 error = pci_setup_msix(sc->bce_dev); 6872 if (error) { 6873 device_printf(sc->bce_dev, "Setup MSI-X failed\n"); 6874 goto back; 6875 } 6876 setup = TRUE; 6877 6878 for (i = 0; i < sc->rx_ring_cnt; ++i) { 6879 msix = &sc->bce_msix[i]; 6880 6881 error = pci_alloc_msix_vector(sc->bce_dev, i, &msix->msix_rid, 6882 msix->msix_cpuid); 6883 if (error) { 6884 device_printf(sc->bce_dev, 6885 "Unable to allocate MSI-X %d on cpu%d\n", 6886 i, msix->msix_cpuid); 6887 goto back; 6888 } 6889 6890 msix->msix_res = bus_alloc_resource_any(sc->bce_dev, 6891 SYS_RES_IRQ, &msix->msix_rid, RF_ACTIVE); 6892 if (msix->msix_res == NULL) { 6893 device_printf(sc->bce_dev, 6894 "Unable to allocate MSI-X %d resource\n", i); 6895 error = ENOMEM; 6896 goto back; 6897 } 6898 } 6899 6900 pci_enable_msix(sc->bce_dev); 6901 sc->bce_irq_type = PCI_INTR_TYPE_MSIX; 6902 back: 6903 if (error) 6904 bce_free_msix(sc, setup); 6905 } 6906 6907 static void 6908 bce_setup_ring_cnt(struct bce_softc *sc) 6909 { 6910 int msix_enable, ring_max, msix_cnt2, msix_cnt, i; 6911 6912 sc->rx_ring_cnt = 1; 6913 sc->rx_ring_cnt2 = 1; 6914 sc->tx_ring_cnt = 1; 6915 6916 if (BCE_CHIP_NUM(sc) != BCE_CHIP_NUM_5709 && 6917 BCE_CHIP_NUM(sc) != BCE_CHIP_NUM_5716) 6918 return; 6919 6920 msix_enable = device_getenv_int(sc->bce_dev, "msix.enable", 6921 bce_msix_enable); 6922 if (!msix_enable) 6923 return; 6924 6925 if (ncpus2 == 1) 6926 return; 6927 6928 msix_cnt = pci_msix_count(sc->bce_dev); 6929 if (msix_cnt <= 1) 6930 return; 6931 6932 i = 0; 6933 while ((1 << (i + 1)) <= msix_cnt) 6934 ++i; 6935 msix_cnt2 = 1 << i; 6936 6937 /* 6938 * One extra RX ring will be needed (see below), so make sure 6939 * that there are enough MSI-X vectors. 6940 */ 6941 if (msix_cnt == msix_cnt2) { 6942 /* 6943 * XXX 6944 * This probably will not happen; 5709/5716 6945 * come with 9 MSI-X vectors. 6946 */ 6947 msix_cnt2 >>= 1; 6948 if (msix_cnt2 <= 1) { 6949 device_printf(sc->bce_dev, 6950 "MSI-X count %d could not be used\n", msix_cnt); 6951 return; 6952 } 6953 device_printf(sc->bce_dev, "MSI-X count %d is power of 2\n", 6954 msix_cnt); 6955 } 6956 6957 /* 6958 * Setup RX ring count 6959 */ 6960 ring_max = BCE_RX_RING_MAX; 6961 if (ring_max > msix_cnt2) 6962 ring_max = msix_cnt2; 6963 sc->rx_ring_cnt2 = device_getenv_int(sc->bce_dev, "rx_rings", 6964 bce_rx_rings); 6965 sc->rx_ring_cnt2 = if_ring_count2(sc->rx_ring_cnt2, ring_max); 6966 6967 /* 6968 * Don't use MSI-X, if the effective RX ring count is 1. 6969 * Since if the effective RX ring count is 1, the TX ring 6970 * count will be 1. This RX ring and the TX ring must be 6971 * bundled into one MSI-X vector, so the hot path will be 6972 * exact same as using MSI. Besides, the first RX ring 6973 * must be fully populated, which only accepts packets whose 6974 * RSS hash can't calculated, e.g. ARP packets; waste of 6975 * resource at least. 6976 */ 6977 if (sc->rx_ring_cnt2 == 1) 6978 return; 6979 6980 /* 6981 * One extra RX ring is allocated, since the first RX ring 6982 * could not be used for RSS hashed packets whose masked 6983 * hash is 0. The first RX ring is only used for packets 6984 * whose RSS hash could not be calculated, e.g. ARP packets. 6985 * This extra RX ring will be used for packets whose masked 6986 * hash is 0. The effective RX ring count involved in RSS 6987 * is still sc->rx_ring_cnt2. 6988 */ 6989 KKASSERT(sc->rx_ring_cnt2 + 1 <= msix_cnt); 6990 sc->rx_ring_cnt = sc->rx_ring_cnt2 + 1; 6991 6992 /* 6993 * Setup TX ring count 6994 * 6995 * NOTE: 6996 * TX ring count must be less than the effective RSS RX ring 6997 * count, since we use RX ring software data struct to save 6998 * status index and various other MSI-X related stuffs. 6999 */ 7000 ring_max = BCE_TX_RING_MAX; 7001 if (ring_max > msix_cnt2) 7002 ring_max = msix_cnt2; 7003 if (ring_max > sc->rx_ring_cnt2) 7004 ring_max = sc->rx_ring_cnt2; 7005 sc->tx_ring_cnt = device_getenv_int(sc->bce_dev, "tx_rings", 7006 bce_tx_rings); 7007 sc->tx_ring_cnt = if_ring_count2(sc->tx_ring_cnt, ring_max); 7008 } 7009 7010 static void 7011 bce_free_msix(struct bce_softc *sc, boolean_t setup) 7012 { 7013 int i; 7014 7015 KKASSERT(sc->rx_ring_cnt > 1); 7016 7017 for (i = 0; i < sc->rx_ring_cnt; ++i) { 7018 struct bce_msix_data *msix = &sc->bce_msix[i]; 7019 7020 if (msix->msix_res != NULL) { 7021 bus_release_resource(sc->bce_dev, SYS_RES_IRQ, 7022 msix->msix_rid, msix->msix_res); 7023 } 7024 if (msix->msix_rid >= 0) 7025 pci_release_msix_vector(sc->bce_dev, msix->msix_rid); 7026 } 7027 if (setup) 7028 pci_teardown_msix(sc->bce_dev); 7029 } 7030 7031 static void 7032 bce_free_intr(struct bce_softc *sc) 7033 { 7034 if (sc->bce_irq_type != PCI_INTR_TYPE_MSIX) { 7035 if (sc->bce_res_irq != NULL) { 7036 bus_release_resource(sc->bce_dev, SYS_RES_IRQ, 7037 sc->bce_irq_rid, sc->bce_res_irq); 7038 } 7039 if (sc->bce_irq_type == PCI_INTR_TYPE_MSI) 7040 pci_release_msi(sc->bce_dev); 7041 } else { 7042 bce_free_msix(sc, TRUE); 7043 } 7044 } 7045 7046 static void 7047 bce_setup_msix_table(struct bce_softc *sc) 7048 { 7049 REG_WR(sc, BCE_PCI_GRC_WINDOW_ADDR, BCE_PCI_GRC_WINDOW_ADDR_SEP_WIN); 7050 REG_WR(sc, BCE_PCI_GRC_WINDOW2_ADDR, BCE_MSIX_TABLE_ADDR); 7051 REG_WR(sc, BCE_PCI_GRC_WINDOW3_ADDR, BCE_MSIX_PBA_ADDR); 7052 } 7053 7054 static int 7055 bce_setup_intr(struct bce_softc *sc) 7056 { 7057 void (*irq_handle)(void *); 7058 int error; 7059 7060 if (sc->bce_irq_type == PCI_INTR_TYPE_MSIX) 7061 return bce_setup_msix(sc); 7062 7063 if (sc->bce_irq_type == PCI_INTR_TYPE_LEGACY) { 7064 irq_handle = bce_intr_legacy; 7065 } else if (sc->bce_irq_type == PCI_INTR_TYPE_MSI) { 7066 if (BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5709 || 7067 BCE_CHIP_NUM(sc) == BCE_CHIP_NUM_5716) { 7068 irq_handle = bce_intr_msi_oneshot; 7069 sc->bce_flags |= BCE_ONESHOT_MSI_FLAG; 7070 } else { 7071 irq_handle = bce_intr_msi; 7072 sc->bce_flags |= BCE_CHECK_MSI_FLAG; 7073 } 7074 } else { 7075 panic("%s: unsupported intr type %d", 7076 device_get_nameunit(sc->bce_dev), sc->bce_irq_type); 7077 } 7078 7079 error = bus_setup_intr(sc->bce_dev, sc->bce_res_irq, INTR_MPSAFE, 7080 irq_handle, sc, &sc->bce_intrhand, &sc->main_serialize); 7081 if (error != 0) { 7082 device_printf(sc->bce_dev, "Failed to setup IRQ!\n"); 7083 return error; 7084 } 7085 7086 return 0; 7087 } 7088 7089 static void 7090 bce_teardown_intr(struct bce_softc *sc) 7091 { 7092 if (sc->bce_irq_type != PCI_INTR_TYPE_MSIX) 7093 bus_teardown_intr(sc->bce_dev, sc->bce_res_irq, sc->bce_intrhand); 7094 else 7095 bce_teardown_msix(sc, sc->rx_ring_cnt); 7096 } 7097 7098 static int 7099 bce_setup_msix(struct bce_softc *sc) 7100 { 7101 int i; 7102 7103 for (i = 0; i < sc->rx_ring_cnt; ++i) { 7104 struct bce_msix_data *msix = &sc->bce_msix[i]; 7105 int error; 7106 7107 error = bus_setup_intr_descr(sc->bce_dev, msix->msix_res, 7108 INTR_MPSAFE, msix->msix_func, msix->msix_arg, 7109 &msix->msix_handle, msix->msix_serialize, msix->msix_desc); 7110 if (error) { 7111 device_printf(sc->bce_dev, "could not set up %s " 7112 "interrupt handler.\n", msix->msix_desc); 7113 bce_teardown_msix(sc, i); 7114 return error; 7115 } 7116 } 7117 return 0; 7118 } 7119 7120 static void 7121 bce_teardown_msix(struct bce_softc *sc, int msix_cnt) 7122 { 7123 int i; 7124 7125 for (i = 0; i < msix_cnt; ++i) { 7126 struct bce_msix_data *msix = &sc->bce_msix[i]; 7127 7128 bus_teardown_intr(sc->bce_dev, msix->msix_res, 7129 msix->msix_handle); 7130 } 7131 } 7132 7133 static void 7134 bce_init_rss(struct bce_softc *sc) 7135 { 7136 uint8_t key[BCE_RLUP_RSS_KEY_CNT * BCE_RLUP_RSS_KEY_SIZE]; 7137 uint32_t tbl = 0; 7138 int i; 7139 7140 KKASSERT(sc->rx_ring_cnt > 2); 7141 7142 /* 7143 * Configure RSS keys 7144 */ 7145 toeplitz_get_key(key, sizeof(key)); 7146 for (i = 0; i < BCE_RLUP_RSS_KEY_CNT; ++i) { 7147 uint32_t rss_key; 7148 7149 rss_key = BCE_RLUP_RSS_KEYVAL(key, i); 7150 BCE_RSS_DPRINTF(sc, 1, "rss_key%d 0x%08x\n", i, rss_key); 7151 7152 REG_WR(sc, BCE_RLUP_RSS_KEY(i), rss_key); 7153 } 7154 7155 /* 7156 * Configure the redirect table 7157 * 7158 * NOTE: 7159 * - The "queue ID" in redirect table is the software RX ring's 7160 * index _minus_ one. 7161 * - The last RX ring, whose "queue ID" is (sc->rx_ring_cnt - 2) 7162 * will be used for packets whose masked hash is 0. 7163 * (see also: comment in bce_setup_ring_cnt()) 7164 * 7165 * The redirect table is configured in following fashion, except 7166 * for the masked hash 0, which is noted above: 7167 * (hash & ring_cnt_mask) == rdr_table[(hash & rdr_table_mask)] 7168 */ 7169 for (i = 0; i < BCE_RXP_SCRATCH_RSS_TBL_MAX_ENTRIES; i++) { 7170 int shift = (i % 8) << 2, qid; 7171 7172 qid = i % sc->rx_ring_cnt2; 7173 if (qid > 0) 7174 --qid; 7175 else 7176 qid = sc->rx_ring_cnt - 2; 7177 KKASSERT(qid < (sc->rx_ring_cnt - 1)); 7178 7179 tbl |= qid << shift; 7180 if (i % 8 == 7) { 7181 BCE_RSS_DPRINTF(sc, 1, "tbl 0x%08x\n", tbl); 7182 REG_WR(sc, BCE_RLUP_RSS_DATA, tbl); 7183 REG_WR(sc, BCE_RLUP_RSS_COMMAND, (i >> 3) | 7184 BCE_RLUP_RSS_COMMAND_RSS_WRITE_MASK | 7185 BCE_RLUP_RSS_COMMAND_WRITE | 7186 BCE_RLUP_RSS_COMMAND_HASH_MASK); 7187 tbl = 0; 7188 } 7189 } 7190 REG_WR(sc, BCE_RLUP_RSS_CONFIG, 7191 BCE_RLUP_RSS_CONFIG_IPV4_RSS_TYPE_ALL_XI); 7192 } 7193 7194 static void 7195 bce_npoll_coal_change(struct bce_softc *sc) 7196 { 7197 uint32_t old_rx_cons, old_tx_cons; 7198 7199 old_rx_cons = sc->bce_rx_quick_cons_trip_int; 7200 old_tx_cons = sc->bce_tx_quick_cons_trip_int; 7201 sc->bce_rx_quick_cons_trip_int = 1; 7202 sc->bce_tx_quick_cons_trip_int = 1; 7203 7204 sc->bce_coalchg_mask |= BCE_COALMASK_TX_BDS_INT | 7205 BCE_COALMASK_RX_BDS_INT; 7206 bce_coal_change(sc); 7207 7208 sc->bce_rx_quick_cons_trip_int = old_rx_cons; 7209 sc->bce_tx_quick_cons_trip_int = old_tx_cons; 7210 } 7211 7212 static struct pktinfo * 7213 bce_rss_pktinfo(struct pktinfo *pi, uint32_t status, 7214 const struct l2_fhdr *l2fhdr) 7215 { 7216 /* Check for an IP datagram. */ 7217 if ((status & L2_FHDR_STATUS_IP_DATAGRAM) == 0) 7218 return NULL; 7219 7220 /* Check if the IP checksum is valid. */ 7221 if (l2fhdr->l2_fhdr_ip_xsum != 0xffff) 7222 return NULL; 7223 7224 /* Check for a valid TCP/UDP frame. */ 7225 if (status & L2_FHDR_STATUS_TCP_SEGMENT) { 7226 if (status & L2_FHDR_ERRORS_TCP_XSUM) 7227 return NULL; 7228 if (l2fhdr->l2_fhdr_tcp_udp_xsum != 0xffff) 7229 return NULL; 7230 pi->pi_l3proto = IPPROTO_TCP; 7231 } else if (status & L2_FHDR_STATUS_UDP_DATAGRAM) { 7232 if (status & L2_FHDR_ERRORS_UDP_XSUM) 7233 return NULL; 7234 if (l2fhdr->l2_fhdr_tcp_udp_xsum != 0xffff) 7235 return NULL; 7236 pi->pi_l3proto = IPPROTO_UDP; 7237 } else { 7238 return NULL; 7239 } 7240 pi->pi_netisr = NETISR_IP; 7241 pi->pi_flags = 0; 7242 7243 return pi; 7244 } 7245