1 /* 2 * QEMU e1000 emulation 3 * 4 * Software developer's manual: 5 * http://download.intel.com/design/network/manuals/8254x_GBe_SDM.pdf 6 * 7 * Nir Peleg, Tutis Systems Ltd. for Qumranet Inc. 8 * Copyright (c) 2008 Qumranet 9 * Based on work done by: 10 * Copyright (c) 2007 Dan Aloni 11 * Copyright (c) 2004 Antony T Curtis 12 * 13 * This library is free software; you can redistribute it and/or 14 * modify it under the terms of the GNU Lesser General Public 15 * License as published by the Free Software Foundation; either 16 * version 2.1 of the License, or (at your option) any later version. 17 * 18 * This library is distributed in the hope that it will be useful, 19 * but WITHOUT ANY WARRANTY; without even the implied warranty of 20 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU 21 * Lesser General Public License for more details. 22 * 23 * You should have received a copy of the GNU Lesser General Public 24 * License along with this library; if not, see <http://www.gnu.org/licenses/>. 25 */ 26 27 28 #include "qemu/osdep.h" 29 #include "hw/net/mii.h" 30 #include "hw/pci/pci_device.h" 31 #include "hw/qdev-properties.h" 32 #include "migration/vmstate.h" 33 #include "net/eth.h" 34 #include "net/net.h" 35 #include "net/checksum.h" 36 #include "sysemu/sysemu.h" 37 #include "sysemu/dma.h" 38 #include "qemu/iov.h" 39 #include "qemu/module.h" 40 #include "qemu/range.h" 41 42 #include "e1000_common.h" 43 #include "e1000x_common.h" 44 #include "trace.h" 45 #include "qom/object.h" 46 47 /* #define E1000_DEBUG */ 48 49 #ifdef E1000_DEBUG 50 enum { 51 DEBUG_GENERAL, DEBUG_IO, DEBUG_MMIO, DEBUG_INTERRUPT, 52 DEBUG_RX, DEBUG_TX, DEBUG_MDIC, DEBUG_EEPROM, 53 DEBUG_UNKNOWN, DEBUG_TXSUM, DEBUG_TXERR, DEBUG_RXERR, 54 DEBUG_RXFILTER, DEBUG_PHY, DEBUG_NOTYET, 55 }; 56 #define DBGBIT(x) (1<<DEBUG_##x) 57 static int debugflags = DBGBIT(TXERR) | DBGBIT(GENERAL); 58 59 #define DBGOUT(what, fmt, ...) do { \ 60 if (debugflags & DBGBIT(what)) \ 61 fprintf(stderr, "e1000: " fmt, ## __VA_ARGS__); \ 62 } while (0) 63 #else 64 #define DBGOUT(what, fmt, ...) do {} while (0) 65 #endif 66 67 #define IOPORT_SIZE 0x40 68 #define PNPMMIO_SIZE 0x20000 69 70 #define MAXIMUM_ETHERNET_HDR_LEN (ETH_HLEN + 4) 71 72 /* 73 * HW models: 74 * E1000_DEV_ID_82540EM works with Windows, Linux, and OS X <= 10.8 75 * E1000_DEV_ID_82544GC_COPPER appears to work; not well tested 76 * E1000_DEV_ID_82545EM_COPPER works with Linux and OS X >= 10.6 77 * Others never tested 78 */ 79 80 struct E1000State_st { 81 /*< private >*/ 82 PCIDevice parent_obj; 83 /*< public >*/ 84 85 NICState *nic; 86 NICConf conf; 87 MemoryRegion mmio; 88 MemoryRegion io; 89 90 uint32_t mac_reg[0x8000]; 91 uint16_t phy_reg[0x20]; 92 uint16_t eeprom_data[64]; 93 94 uint32_t rxbuf_size; 95 uint32_t rxbuf_min_shift; 96 struct e1000_tx { 97 unsigned char header[256]; 98 unsigned char vlan_header[4]; 99 /* Fields vlan and data must not be reordered or separated. */ 100 unsigned char vlan[4]; 101 unsigned char data[0x10000]; 102 uint16_t size; 103 unsigned char vlan_needed; 104 unsigned char sum_needed; 105 bool cptse; 106 e1000x_txd_props props; 107 e1000x_txd_props tso_props; 108 uint16_t tso_frames; 109 bool busy; 110 } tx; 111 112 struct { 113 uint32_t val_in; /* shifted in from guest driver */ 114 uint16_t bitnum_in; 115 uint16_t bitnum_out; 116 uint16_t reading; 117 uint32_t old_eecd; 118 } eecd_state; 119 120 QEMUTimer *autoneg_timer; 121 122 QEMUTimer *mit_timer; /* Mitigation timer. */ 123 bool mit_timer_on; /* Mitigation timer is running. */ 124 bool mit_irq_level; /* Tracks interrupt pin level. */ 125 uint32_t mit_ide; /* Tracks E1000_TXD_CMD_IDE bit. */ 126 127 QEMUTimer *flush_queue_timer; 128 129 /* Compatibility flags for migration to/from qemu 1.3.0 and older */ 130 #define E1000_FLAG_MAC_BIT 2 131 #define E1000_FLAG_TSO_BIT 3 132 #define E1000_FLAG_VET_BIT 4 133 #define E1000_FLAG_MAC (1 << E1000_FLAG_MAC_BIT) 134 #define E1000_FLAG_TSO (1 << E1000_FLAG_TSO_BIT) 135 #define E1000_FLAG_VET (1 << E1000_FLAG_VET_BIT) 136 137 uint32_t compat_flags; 138 bool received_tx_tso; 139 bool use_tso_for_migration; 140 e1000x_txd_props mig_props; 141 }; 142 typedef struct E1000State_st E1000State; 143 144 #define chkflag(x) (s->compat_flags & E1000_FLAG_##x) 145 146 struct E1000BaseClass { 147 PCIDeviceClass parent_class; 148 uint16_t phy_id2; 149 }; 150 typedef struct E1000BaseClass E1000BaseClass; 151 152 #define TYPE_E1000_BASE "e1000-base" 153 154 DECLARE_OBJ_CHECKERS(E1000State, E1000BaseClass, 155 E1000, TYPE_E1000_BASE) 156 157 158 static void 159 e1000_link_up(E1000State *s) 160 { 161 e1000x_update_regs_on_link_up(s->mac_reg, s->phy_reg); 162 163 /* E1000_STATUS_LU is tested by e1000_can_receive() */ 164 qemu_flush_queued_packets(qemu_get_queue(s->nic)); 165 } 166 167 static void 168 e1000_autoneg_done(E1000State *s) 169 { 170 e1000x_update_regs_on_autoneg_done(s->mac_reg, s->phy_reg); 171 172 /* E1000_STATUS_LU is tested by e1000_can_receive() */ 173 qemu_flush_queued_packets(qemu_get_queue(s->nic)); 174 } 175 176 static bool 177 have_autoneg(E1000State *s) 178 { 179 return (s->phy_reg[MII_BMCR] & MII_BMCR_AUTOEN); 180 } 181 182 static void 183 set_phy_ctrl(E1000State *s, int index, uint16_t val) 184 { 185 /* bits 0-5 reserved; MII_BMCR_[ANRESTART,RESET] are self clearing */ 186 s->phy_reg[MII_BMCR] = val & ~(0x3f | 187 MII_BMCR_RESET | 188 MII_BMCR_ANRESTART); 189 190 /* 191 * QEMU 1.3 does not support link auto-negotiation emulation, so if we 192 * migrate during auto negotiation, after migration the link will be 193 * down. 194 */ 195 if (have_autoneg(s) && (val & MII_BMCR_ANRESTART)) { 196 e1000x_restart_autoneg(s->mac_reg, s->phy_reg, s->autoneg_timer); 197 } 198 } 199 200 static void (*phyreg_writeops[])(E1000State *, int, uint16_t) = { 201 [MII_BMCR] = set_phy_ctrl, 202 }; 203 204 enum { NPHYWRITEOPS = ARRAY_SIZE(phyreg_writeops) }; 205 206 enum { PHY_R = 1, PHY_W = 2, PHY_RW = PHY_R | PHY_W }; 207 static const char phy_regcap[0x20] = { 208 [MII_BMSR] = PHY_R, [M88E1000_EXT_PHY_SPEC_CTRL] = PHY_RW, 209 [MII_PHYID1] = PHY_R, [M88E1000_PHY_SPEC_CTRL] = PHY_RW, 210 [MII_BMCR] = PHY_RW, [MII_CTRL1000] = PHY_RW, 211 [MII_ANLPAR] = PHY_R, [MII_STAT1000] = PHY_R, 212 [MII_ANAR] = PHY_RW, [M88E1000_RX_ERR_CNTR] = PHY_R, 213 [MII_PHYID2] = PHY_R, [M88E1000_PHY_SPEC_STATUS] = PHY_R, 214 [MII_ANER] = PHY_R, 215 }; 216 217 /* MII_PHYID2 documented in 8254x_GBe_SDM.pdf, pp. 250 */ 218 static const uint16_t phy_reg_init[] = { 219 [MII_BMCR] = MII_BMCR_SPEED1000 | 220 MII_BMCR_FD | 221 MII_BMCR_AUTOEN, 222 223 [MII_BMSR] = MII_BMSR_EXTCAP | 224 MII_BMSR_LINK_ST | /* link initially up */ 225 MII_BMSR_AUTONEG | 226 /* MII_BMSR_AN_COMP: initially NOT completed */ 227 MII_BMSR_MFPS | 228 MII_BMSR_EXTSTAT | 229 MII_BMSR_10T_HD | 230 MII_BMSR_10T_FD | 231 MII_BMSR_100TX_HD | 232 MII_BMSR_100TX_FD, 233 234 [MII_PHYID1] = 0x141, 235 /* [MII_PHYID2] configured per DevId, from e1000_reset() */ 236 [MII_ANAR] = MII_ANAR_CSMACD | MII_ANAR_10 | 237 MII_ANAR_10FD | MII_ANAR_TX | 238 MII_ANAR_TXFD | MII_ANAR_PAUSE | 239 MII_ANAR_PAUSE_ASYM, 240 [MII_ANLPAR] = MII_ANLPAR_10 | MII_ANLPAR_10FD | 241 MII_ANLPAR_TX | MII_ANLPAR_TXFD, 242 [MII_CTRL1000] = MII_CTRL1000_FULL | MII_CTRL1000_PORT | 243 MII_CTRL1000_MASTER, 244 [MII_STAT1000] = MII_STAT1000_HALF | MII_STAT1000_FULL | 245 MII_STAT1000_ROK | MII_STAT1000_LOK, 246 [M88E1000_PHY_SPEC_CTRL] = 0x360, 247 [M88E1000_PHY_SPEC_STATUS] = 0xac00, 248 [M88E1000_EXT_PHY_SPEC_CTRL] = 0x0d60, 249 }; 250 251 static const uint32_t mac_reg_init[] = { 252 [PBA] = 0x00100030, 253 [LEDCTL] = 0x602, 254 [CTRL] = E1000_CTRL_SWDPIN2 | E1000_CTRL_SWDPIN0 | 255 E1000_CTRL_SPD_1000 | E1000_CTRL_SLU, 256 [STATUS] = 0x80000000 | E1000_STATUS_GIO_MASTER_ENABLE | 257 E1000_STATUS_ASDV | E1000_STATUS_MTXCKOK | 258 E1000_STATUS_SPEED_1000 | E1000_STATUS_FD | 259 E1000_STATUS_LU, 260 [MANC] = E1000_MANC_EN_MNG2HOST | E1000_MANC_RCV_TCO_EN | 261 E1000_MANC_ARP_EN | E1000_MANC_0298_EN | 262 E1000_MANC_RMCP_EN, 263 }; 264 265 /* Helper function, *curr == 0 means the value is not set */ 266 static inline void 267 mit_update_delay(uint32_t *curr, uint32_t value) 268 { 269 if (value && (*curr == 0 || value < *curr)) { 270 *curr = value; 271 } 272 } 273 274 static void 275 set_interrupt_cause(E1000State *s, int index, uint32_t val) 276 { 277 PCIDevice *d = PCI_DEVICE(s); 278 uint32_t pending_ints; 279 uint32_t mit_delay; 280 281 s->mac_reg[ICR] = val; 282 283 /* 284 * Make sure ICR and ICS registers have the same value. 285 * The spec says that the ICS register is write-only. However in practice, 286 * on real hardware ICS is readable, and for reads it has the same value as 287 * ICR (except that ICS does not have the clear on read behaviour of ICR). 288 * 289 * The VxWorks PRO/1000 driver uses this behaviour. 290 */ 291 s->mac_reg[ICS] = val; 292 293 pending_ints = (s->mac_reg[IMS] & s->mac_reg[ICR]); 294 if (!s->mit_irq_level && pending_ints) { 295 /* 296 * Here we detect a potential raising edge. We postpone raising the 297 * interrupt line if we are inside the mitigation delay window 298 * (s->mit_timer_on == 1). 299 * We provide a partial implementation of interrupt mitigation, 300 * emulating only RADV, TADV and ITR (lower 16 bits, 1024ns units for 301 * RADV and TADV, 256ns units for ITR). RDTR is only used to enable 302 * RADV; relative timers based on TIDV and RDTR are not implemented. 303 */ 304 if (s->mit_timer_on) { 305 return; 306 } 307 308 /* Compute the next mitigation delay according to pending 309 * interrupts and the current values of RADV (provided 310 * RDTR!=0), TADV and ITR. 311 * Then rearm the timer. 312 */ 313 mit_delay = 0; 314 if (s->mit_ide && 315 (pending_ints & (E1000_ICR_TXQE | E1000_ICR_TXDW))) { 316 mit_update_delay(&mit_delay, s->mac_reg[TADV] * 4); 317 } 318 if (s->mac_reg[RDTR] && (pending_ints & E1000_ICS_RXT0)) { 319 mit_update_delay(&mit_delay, s->mac_reg[RADV] * 4); 320 } 321 mit_update_delay(&mit_delay, s->mac_reg[ITR]); 322 323 /* 324 * According to e1000 SPEC, the Ethernet controller guarantees 325 * a maximum observable interrupt rate of 7813 interrupts/sec. 326 * Thus if mit_delay < 500 then the delay should be set to the 327 * minimum delay possible which is 500. 328 */ 329 mit_delay = (mit_delay < 500) ? 500 : mit_delay; 330 331 s->mit_timer_on = 1; 332 timer_mod(s->mit_timer, qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL) + 333 mit_delay * 256); 334 s->mit_ide = 0; 335 } 336 337 s->mit_irq_level = (pending_ints != 0); 338 pci_set_irq(d, s->mit_irq_level); 339 } 340 341 static void 342 e1000_mit_timer(void *opaque) 343 { 344 E1000State *s = opaque; 345 346 s->mit_timer_on = 0; 347 /* Call set_interrupt_cause to update the irq level (if necessary). */ 348 set_interrupt_cause(s, 0, s->mac_reg[ICR]); 349 } 350 351 static void 352 set_ics(E1000State *s, int index, uint32_t val) 353 { 354 DBGOUT(INTERRUPT, "set_ics %x, ICR %x, IMR %x\n", val, s->mac_reg[ICR], 355 s->mac_reg[IMS]); 356 set_interrupt_cause(s, 0, val | s->mac_reg[ICR]); 357 } 358 359 static void 360 e1000_autoneg_timer(void *opaque) 361 { 362 E1000State *s = opaque; 363 if (!qemu_get_queue(s->nic)->link_down) { 364 e1000_autoneg_done(s); 365 set_ics(s, 0, E1000_ICS_LSC); /* signal link status change to guest */ 366 } 367 } 368 369 static bool e1000_vet_init_need(void *opaque) 370 { 371 E1000State *s = opaque; 372 373 return chkflag(VET); 374 } 375 376 static void e1000_reset_hold(Object *obj, ResetType type) 377 { 378 E1000State *d = E1000(obj); 379 E1000BaseClass *edc = E1000_GET_CLASS(d); 380 uint8_t *macaddr = d->conf.macaddr.a; 381 382 timer_del(d->autoneg_timer); 383 timer_del(d->mit_timer); 384 timer_del(d->flush_queue_timer); 385 d->mit_timer_on = 0; 386 d->mit_irq_level = 0; 387 d->mit_ide = 0; 388 memset(d->phy_reg, 0, sizeof d->phy_reg); 389 memcpy(d->phy_reg, phy_reg_init, sizeof phy_reg_init); 390 d->phy_reg[MII_PHYID2] = edc->phy_id2; 391 memset(d->mac_reg, 0, sizeof d->mac_reg); 392 memcpy(d->mac_reg, mac_reg_init, sizeof mac_reg_init); 393 d->rxbuf_min_shift = 1; 394 memset(&d->tx, 0, sizeof d->tx); 395 396 if (qemu_get_queue(d->nic)->link_down) { 397 e1000x_update_regs_on_link_down(d->mac_reg, d->phy_reg); 398 } 399 400 e1000x_reset_mac_addr(d->nic, d->mac_reg, macaddr); 401 402 if (e1000_vet_init_need(d)) { 403 d->mac_reg[VET] = ETH_P_VLAN; 404 } 405 } 406 407 static void 408 set_ctrl(E1000State *s, int index, uint32_t val) 409 { 410 /* RST is self clearing */ 411 s->mac_reg[CTRL] = val & ~E1000_CTRL_RST; 412 } 413 414 static void 415 e1000_flush_queue_timer(void *opaque) 416 { 417 E1000State *s = opaque; 418 419 qemu_flush_queued_packets(qemu_get_queue(s->nic)); 420 } 421 422 static void 423 set_rx_control(E1000State *s, int index, uint32_t val) 424 { 425 s->mac_reg[RCTL] = val; 426 s->rxbuf_size = e1000x_rxbufsize(val); 427 s->rxbuf_min_shift = ((val / E1000_RCTL_RDMTS_QUAT) & 3) + 1; 428 DBGOUT(RX, "RCTL: %d, mac_reg[RCTL] = 0x%x\n", s->mac_reg[RDT], 429 s->mac_reg[RCTL]); 430 timer_mod(s->flush_queue_timer, 431 qemu_clock_get_ms(QEMU_CLOCK_VIRTUAL) + 1000); 432 } 433 434 static void 435 set_mdic(E1000State *s, int index, uint32_t val) 436 { 437 uint32_t data = val & E1000_MDIC_DATA_MASK; 438 uint32_t addr = ((val & E1000_MDIC_REG_MASK) >> E1000_MDIC_REG_SHIFT); 439 440 if ((val & E1000_MDIC_PHY_MASK) >> E1000_MDIC_PHY_SHIFT != 1) // phy # 441 val = s->mac_reg[MDIC] | E1000_MDIC_ERROR; 442 else if (val & E1000_MDIC_OP_READ) { 443 DBGOUT(MDIC, "MDIC read reg 0x%x\n", addr); 444 if (!(phy_regcap[addr] & PHY_R)) { 445 DBGOUT(MDIC, "MDIC read reg %x unhandled\n", addr); 446 val |= E1000_MDIC_ERROR; 447 } else 448 val = (val ^ data) | s->phy_reg[addr]; 449 } else if (val & E1000_MDIC_OP_WRITE) { 450 DBGOUT(MDIC, "MDIC write reg 0x%x, value 0x%x\n", addr, data); 451 if (!(phy_regcap[addr] & PHY_W)) { 452 DBGOUT(MDIC, "MDIC write reg %x unhandled\n", addr); 453 val |= E1000_MDIC_ERROR; 454 } else { 455 if (addr < NPHYWRITEOPS && phyreg_writeops[addr]) { 456 phyreg_writeops[addr](s, index, data); 457 } else { 458 s->phy_reg[addr] = data; 459 } 460 } 461 } 462 s->mac_reg[MDIC] = val | E1000_MDIC_READY; 463 464 if (val & E1000_MDIC_INT_EN) { 465 set_ics(s, 0, E1000_ICR_MDAC); 466 } 467 } 468 469 static uint32_t 470 get_eecd(E1000State *s, int index) 471 { 472 uint32_t ret = E1000_EECD_PRES|E1000_EECD_GNT | s->eecd_state.old_eecd; 473 474 DBGOUT(EEPROM, "reading eeprom bit %d (reading %d)\n", 475 s->eecd_state.bitnum_out, s->eecd_state.reading); 476 if (!s->eecd_state.reading || 477 ((s->eeprom_data[(s->eecd_state.bitnum_out >> 4) & 0x3f] >> 478 ((s->eecd_state.bitnum_out & 0xf) ^ 0xf))) & 1) 479 ret |= E1000_EECD_DO; 480 return ret; 481 } 482 483 static void 484 set_eecd(E1000State *s, int index, uint32_t val) 485 { 486 uint32_t oldval = s->eecd_state.old_eecd; 487 488 s->eecd_state.old_eecd = val & (E1000_EECD_SK | E1000_EECD_CS | 489 E1000_EECD_DI|E1000_EECD_FWE_MASK|E1000_EECD_REQ); 490 if (!(E1000_EECD_CS & val)) { /* CS inactive; nothing to do */ 491 return; 492 } 493 if (E1000_EECD_CS & (val ^ oldval)) { /* CS rise edge; reset state */ 494 s->eecd_state.val_in = 0; 495 s->eecd_state.bitnum_in = 0; 496 s->eecd_state.bitnum_out = 0; 497 s->eecd_state.reading = 0; 498 } 499 if (!(E1000_EECD_SK & (val ^ oldval))) { /* no clock edge */ 500 return; 501 } 502 if (!(E1000_EECD_SK & val)) { /* falling edge */ 503 s->eecd_state.bitnum_out++; 504 return; 505 } 506 s->eecd_state.val_in <<= 1; 507 if (val & E1000_EECD_DI) 508 s->eecd_state.val_in |= 1; 509 if (++s->eecd_state.bitnum_in == 9 && !s->eecd_state.reading) { 510 s->eecd_state.bitnum_out = ((s->eecd_state.val_in & 0x3f)<<4)-1; 511 s->eecd_state.reading = (((s->eecd_state.val_in >> 6) & 7) == 512 EEPROM_READ_OPCODE_MICROWIRE); 513 } 514 DBGOUT(EEPROM, "eeprom bitnum in %d out %d, reading %d\n", 515 s->eecd_state.bitnum_in, s->eecd_state.bitnum_out, 516 s->eecd_state.reading); 517 } 518 519 static uint32_t 520 flash_eerd_read(E1000State *s, int x) 521 { 522 unsigned int index, r = s->mac_reg[EERD] & ~E1000_EEPROM_RW_REG_START; 523 524 if ((s->mac_reg[EERD] & E1000_EEPROM_RW_REG_START) == 0) 525 return (s->mac_reg[EERD]); 526 527 if ((index = r >> E1000_EEPROM_RW_ADDR_SHIFT) > EEPROM_CHECKSUM_REG) 528 return (E1000_EEPROM_RW_REG_DONE | r); 529 530 return ((s->eeprom_data[index] << E1000_EEPROM_RW_REG_DATA) | 531 E1000_EEPROM_RW_REG_DONE | r); 532 } 533 534 static void 535 putsum(uint8_t *data, uint32_t n, uint32_t sloc, uint32_t css, uint32_t cse) 536 { 537 uint32_t sum; 538 539 if (cse && cse < n) 540 n = cse + 1; 541 if (sloc < n-1) { 542 sum = net_checksum_add(n-css, data+css); 543 stw_be_p(data + sloc, net_checksum_finish_nozero(sum)); 544 } 545 } 546 547 static inline void 548 inc_tx_bcast_or_mcast_count(E1000State *s, const unsigned char *arr) 549 { 550 if (is_broadcast_ether_addr(arr)) { 551 e1000x_inc_reg_if_not_full(s->mac_reg, BPTC); 552 } else if (is_multicast_ether_addr(arr)) { 553 e1000x_inc_reg_if_not_full(s->mac_reg, MPTC); 554 } 555 } 556 557 static void 558 e1000_send_packet(E1000State *s, const uint8_t *buf, int size) 559 { 560 static const int PTCregs[6] = { PTC64, PTC127, PTC255, PTC511, 561 PTC1023, PTC1522 }; 562 563 NetClientState *nc = qemu_get_queue(s->nic); 564 if (s->phy_reg[MII_BMCR] & MII_BMCR_LOOPBACK) { 565 qemu_receive_packet(nc, buf, size); 566 } else { 567 qemu_send_packet(nc, buf, size); 568 } 569 inc_tx_bcast_or_mcast_count(s, buf); 570 e1000x_increase_size_stats(s->mac_reg, PTCregs, size + 4); 571 } 572 573 static void 574 xmit_seg(E1000State *s) 575 { 576 uint16_t len; 577 unsigned int frames = s->tx.tso_frames, css, sofar; 578 struct e1000_tx *tp = &s->tx; 579 struct e1000x_txd_props *props = tp->cptse ? &tp->tso_props : &tp->props; 580 581 if (tp->cptse) { 582 css = props->ipcss; 583 DBGOUT(TXSUM, "frames %d size %d ipcss %d\n", 584 frames, tp->size, css); 585 if (props->ip) { /* IPv4 */ 586 stw_be_p(tp->data+css+2, tp->size - css); 587 stw_be_p(tp->data+css+4, 588 lduw_be_p(tp->data + css + 4) + frames); 589 } else { /* IPv6 */ 590 stw_be_p(tp->data+css+4, tp->size - css); 591 } 592 css = props->tucss; 593 len = tp->size - css; 594 DBGOUT(TXSUM, "tcp %d tucss %d len %d\n", props->tcp, css, len); 595 if (props->tcp) { 596 sofar = frames * props->mss; 597 stl_be_p(tp->data+css+4, ldl_be_p(tp->data+css+4)+sofar); /* seq */ 598 if (props->paylen - sofar > props->mss) { 599 tp->data[css + 13] &= ~9; /* PSH, FIN */ 600 } else if (frames) { 601 e1000x_inc_reg_if_not_full(s->mac_reg, TSCTC); 602 } 603 } else { /* UDP */ 604 stw_be_p(tp->data+css+4, len); 605 } 606 if (tp->sum_needed & E1000_TXD_POPTS_TXSM) { 607 unsigned int phsum; 608 // add pseudo-header length before checksum calculation 609 void *sp = tp->data + props->tucso; 610 611 phsum = lduw_be_p(sp) + len; 612 phsum = (phsum >> 16) + (phsum & 0xffff); 613 stw_be_p(sp, phsum); 614 } 615 tp->tso_frames++; 616 } 617 618 if (tp->sum_needed & E1000_TXD_POPTS_TXSM) { 619 putsum(tp->data, tp->size, props->tucso, props->tucss, props->tucse); 620 } 621 if (tp->sum_needed & E1000_TXD_POPTS_IXSM) { 622 putsum(tp->data, tp->size, props->ipcso, props->ipcss, props->ipcse); 623 } 624 if (tp->vlan_needed) { 625 memmove(tp->vlan, tp->data, 4); 626 memmove(tp->data, tp->data + 4, 8); 627 memcpy(tp->data + 8, tp->vlan_header, 4); 628 e1000_send_packet(s, tp->vlan, tp->size + 4); 629 } else { 630 e1000_send_packet(s, tp->data, tp->size); 631 } 632 633 e1000x_inc_reg_if_not_full(s->mac_reg, TPT); 634 e1000x_grow_8reg_if_not_full(s->mac_reg, TOTL, s->tx.size + 4); 635 e1000x_inc_reg_if_not_full(s->mac_reg, GPTC); 636 e1000x_grow_8reg_if_not_full(s->mac_reg, GOTCL, s->tx.size + 4); 637 } 638 639 static void 640 process_tx_desc(E1000State *s, struct e1000_tx_desc *dp) 641 { 642 PCIDevice *d = PCI_DEVICE(s); 643 uint32_t txd_lower = le32_to_cpu(dp->lower.data); 644 uint32_t dtype = txd_lower & (E1000_TXD_CMD_DEXT | E1000_TXD_DTYP_D); 645 unsigned int split_size = txd_lower & 0xffff, bytes, sz; 646 unsigned int msh = 0xfffff; 647 uint64_t addr; 648 struct e1000_context_desc *xp = (struct e1000_context_desc *)dp; 649 struct e1000_tx *tp = &s->tx; 650 651 s->mit_ide |= (txd_lower & E1000_TXD_CMD_IDE); 652 if (dtype == E1000_TXD_CMD_DEXT) { /* context descriptor */ 653 if (le32_to_cpu(xp->cmd_and_length) & E1000_TXD_CMD_TSE) { 654 e1000x_read_tx_ctx_descr(xp, &tp->tso_props); 655 s->use_tso_for_migration = 1; 656 tp->tso_frames = 0; 657 } else { 658 e1000x_read_tx_ctx_descr(xp, &tp->props); 659 s->use_tso_for_migration = 0; 660 } 661 return; 662 } else if (dtype == (E1000_TXD_CMD_DEXT | E1000_TXD_DTYP_D)) { 663 // data descriptor 664 if (tp->size == 0) { 665 tp->sum_needed = le32_to_cpu(dp->upper.data) >> 8; 666 } 667 tp->cptse = (txd_lower & E1000_TXD_CMD_TSE) ? 1 : 0; 668 } else { 669 // legacy descriptor 670 tp->cptse = 0; 671 } 672 673 if (e1000x_vlan_enabled(s->mac_reg) && 674 e1000x_is_vlan_txd(txd_lower) && 675 (tp->cptse || txd_lower & E1000_TXD_CMD_EOP)) { 676 tp->vlan_needed = 1; 677 stw_be_p(tp->vlan_header, 678 le16_to_cpu(s->mac_reg[VET])); 679 stw_be_p(tp->vlan_header + 2, 680 le16_to_cpu(dp->upper.fields.special)); 681 } 682 683 addr = le64_to_cpu(dp->buffer_addr); 684 if (tp->cptse) { 685 msh = tp->tso_props.hdr_len + tp->tso_props.mss; 686 do { 687 bytes = split_size; 688 if (tp->size >= msh) { 689 goto eop; 690 } 691 if (tp->size + bytes > msh) 692 bytes = msh - tp->size; 693 694 bytes = MIN(sizeof(tp->data) - tp->size, bytes); 695 pci_dma_read(d, addr, tp->data + tp->size, bytes); 696 sz = tp->size + bytes; 697 if (sz >= tp->tso_props.hdr_len 698 && tp->size < tp->tso_props.hdr_len) { 699 memmove(tp->header, tp->data, tp->tso_props.hdr_len); 700 } 701 tp->size = sz; 702 addr += bytes; 703 if (sz == msh) { 704 xmit_seg(s); 705 memmove(tp->data, tp->header, tp->tso_props.hdr_len); 706 tp->size = tp->tso_props.hdr_len; 707 } 708 split_size -= bytes; 709 } while (bytes && split_size); 710 } else { 711 split_size = MIN(sizeof(tp->data) - tp->size, split_size); 712 pci_dma_read(d, addr, tp->data + tp->size, split_size); 713 tp->size += split_size; 714 } 715 716 eop: 717 if (!(txd_lower & E1000_TXD_CMD_EOP)) 718 return; 719 if (!(tp->cptse && tp->size < tp->tso_props.hdr_len)) { 720 xmit_seg(s); 721 } 722 tp->tso_frames = 0; 723 tp->sum_needed = 0; 724 tp->vlan_needed = 0; 725 tp->size = 0; 726 tp->cptse = 0; 727 } 728 729 static uint32_t 730 txdesc_writeback(E1000State *s, dma_addr_t base, struct e1000_tx_desc *dp) 731 { 732 PCIDevice *d = PCI_DEVICE(s); 733 uint32_t txd_upper, txd_lower = le32_to_cpu(dp->lower.data); 734 735 if (!(txd_lower & (E1000_TXD_CMD_RS|E1000_TXD_CMD_RPS))) 736 return 0; 737 txd_upper = (le32_to_cpu(dp->upper.data) | E1000_TXD_STAT_DD) & 738 ~(E1000_TXD_STAT_EC | E1000_TXD_STAT_LC | E1000_TXD_STAT_TU); 739 dp->upper.data = cpu_to_le32(txd_upper); 740 pci_dma_write(d, base + ((char *)&dp->upper - (char *)dp), 741 &dp->upper, sizeof(dp->upper)); 742 return E1000_ICR_TXDW; 743 } 744 745 static uint64_t tx_desc_base(E1000State *s) 746 { 747 uint64_t bah = s->mac_reg[TDBAH]; 748 uint64_t bal = s->mac_reg[TDBAL] & ~0xf; 749 750 return (bah << 32) + bal; 751 } 752 753 static void 754 start_xmit(E1000State *s) 755 { 756 PCIDevice *d = PCI_DEVICE(s); 757 dma_addr_t base; 758 struct e1000_tx_desc desc; 759 uint32_t tdh_start = s->mac_reg[TDH], cause = E1000_ICS_TXQE; 760 761 if (!(s->mac_reg[TCTL] & E1000_TCTL_EN)) { 762 DBGOUT(TX, "tx disabled\n"); 763 return; 764 } 765 766 if (s->tx.busy) { 767 return; 768 } 769 s->tx.busy = true; 770 771 while (s->mac_reg[TDH] != s->mac_reg[TDT]) { 772 base = tx_desc_base(s) + 773 sizeof(struct e1000_tx_desc) * s->mac_reg[TDH]; 774 pci_dma_read(d, base, &desc, sizeof(desc)); 775 776 DBGOUT(TX, "index %d: %p : %x %x\n", s->mac_reg[TDH], 777 (void *)(intptr_t)desc.buffer_addr, desc.lower.data, 778 desc.upper.data); 779 780 process_tx_desc(s, &desc); 781 cause |= txdesc_writeback(s, base, &desc); 782 783 if (++s->mac_reg[TDH] * sizeof(desc) >= s->mac_reg[TDLEN]) 784 s->mac_reg[TDH] = 0; 785 /* 786 * the following could happen only if guest sw assigns 787 * bogus values to TDT/TDLEN. 788 * there's nothing too intelligent we could do about this. 789 */ 790 if (s->mac_reg[TDH] == tdh_start || 791 tdh_start >= s->mac_reg[TDLEN] / sizeof(desc)) { 792 DBGOUT(TXERR, "TDH wraparound @%x, TDT %x, TDLEN %x\n", 793 tdh_start, s->mac_reg[TDT], s->mac_reg[TDLEN]); 794 break; 795 } 796 } 797 s->tx.busy = false; 798 set_ics(s, 0, cause); 799 } 800 801 static int 802 receive_filter(E1000State *s, const void *buf) 803 { 804 return (!e1000x_is_vlan_packet(buf, s->mac_reg[VET]) || 805 e1000x_rx_vlan_filter(s->mac_reg, PKT_GET_VLAN_HDR(buf))) && 806 e1000x_rx_group_filter(s->mac_reg, buf); 807 } 808 809 static void 810 e1000_set_link_status(NetClientState *nc) 811 { 812 E1000State *s = qemu_get_nic_opaque(nc); 813 uint32_t old_status = s->mac_reg[STATUS]; 814 815 if (nc->link_down) { 816 e1000x_update_regs_on_link_down(s->mac_reg, s->phy_reg); 817 } else { 818 if (have_autoneg(s) && 819 !(s->phy_reg[MII_BMSR] & MII_BMSR_AN_COMP)) { 820 e1000x_restart_autoneg(s->mac_reg, s->phy_reg, s->autoneg_timer); 821 } else { 822 e1000_link_up(s); 823 } 824 } 825 826 if (s->mac_reg[STATUS] != old_status) 827 set_ics(s, 0, E1000_ICR_LSC); 828 } 829 830 static bool e1000_has_rxbufs(E1000State *s, size_t total_size) 831 { 832 int bufs; 833 /* Fast-path short packets */ 834 if (total_size <= s->rxbuf_size) { 835 return s->mac_reg[RDH] != s->mac_reg[RDT]; 836 } 837 if (s->mac_reg[RDH] < s->mac_reg[RDT]) { 838 bufs = s->mac_reg[RDT] - s->mac_reg[RDH]; 839 } else if (s->mac_reg[RDH] > s->mac_reg[RDT]) { 840 bufs = s->mac_reg[RDLEN] / sizeof(struct e1000_rx_desc) + 841 s->mac_reg[RDT] - s->mac_reg[RDH]; 842 } else { 843 return false; 844 } 845 return total_size <= bufs * s->rxbuf_size; 846 } 847 848 static bool 849 e1000_can_receive(NetClientState *nc) 850 { 851 E1000State *s = qemu_get_nic_opaque(nc); 852 853 return e1000x_rx_ready(&s->parent_obj, s->mac_reg) && 854 e1000_has_rxbufs(s, 1) && !timer_pending(s->flush_queue_timer); 855 } 856 857 static uint64_t rx_desc_base(E1000State *s) 858 { 859 uint64_t bah = s->mac_reg[RDBAH]; 860 uint64_t bal = s->mac_reg[RDBAL] & ~0xf; 861 862 return (bah << 32) + bal; 863 } 864 865 static void 866 e1000_receiver_overrun(E1000State *s, size_t size) 867 { 868 trace_e1000_receiver_overrun(size, s->mac_reg[RDH], s->mac_reg[RDT]); 869 e1000x_inc_reg_if_not_full(s->mac_reg, RNBC); 870 e1000x_inc_reg_if_not_full(s->mac_reg, MPC); 871 set_ics(s, 0, E1000_ICS_RXO); 872 } 873 874 static ssize_t 875 e1000_receive_iov(NetClientState *nc, const struct iovec *iov, int iovcnt) 876 { 877 E1000State *s = qemu_get_nic_opaque(nc); 878 PCIDevice *d = PCI_DEVICE(s); 879 struct e1000_rx_desc desc; 880 dma_addr_t base; 881 unsigned int n, rdt; 882 uint32_t rdh_start; 883 uint16_t vlan_special = 0; 884 uint8_t vlan_status = 0; 885 uint8_t min_buf[ETH_ZLEN]; 886 uint8_t *filter_buf = iov->iov_base; 887 size_t size = iov_size(iov, iovcnt); 888 size_t iov_ofs = 0; 889 size_t desc_offset; 890 size_t desc_size; 891 size_t total_size; 892 eth_pkt_types_e pkt_type; 893 894 if (!e1000x_hw_rx_enabled(s->mac_reg)) { 895 return -1; 896 } 897 898 if (timer_pending(s->flush_queue_timer)) { 899 return 0; 900 } 901 902 if (iov->iov_len < MAXIMUM_ETHERNET_HDR_LEN) { 903 /* This is very unlikely, but may happen. */ 904 iov_to_buf(iov, iovcnt, 0, min_buf, MAXIMUM_ETHERNET_HDR_LEN); 905 filter_buf = min_buf; 906 } 907 908 /* Discard oversized packets if !LPE and !SBP. */ 909 if (e1000x_is_oversized(s->mac_reg, size)) { 910 return size; 911 } 912 913 if (!receive_filter(s, filter_buf)) { 914 return size; 915 } 916 917 if (e1000x_vlan_enabled(s->mac_reg) && 918 e1000x_is_vlan_packet(filter_buf, le16_to_cpu(s->mac_reg[VET]))) { 919 vlan_special = cpu_to_le16(lduw_be_p(filter_buf + 14)); 920 iov_ofs = 4; 921 if (filter_buf == iov->iov_base) { 922 memmove(filter_buf + 4, filter_buf, 12); 923 } else { 924 iov_from_buf(iov, iovcnt, 4, filter_buf, 12); 925 while (iov->iov_len <= iov_ofs) { 926 iov_ofs -= iov->iov_len; 927 iov++; 928 } 929 } 930 vlan_status = E1000_RXD_STAT_VP; 931 size -= 4; 932 } 933 934 pkt_type = get_eth_packet_type(PKT_GET_ETH_HDR(filter_buf)); 935 rdh_start = s->mac_reg[RDH]; 936 desc_offset = 0; 937 total_size = size + e1000x_fcs_len(s->mac_reg); 938 if (!e1000_has_rxbufs(s, total_size)) { 939 e1000_receiver_overrun(s, total_size); 940 return -1; 941 } 942 do { 943 desc_size = total_size - desc_offset; 944 if (desc_size > s->rxbuf_size) { 945 desc_size = s->rxbuf_size; 946 } 947 base = rx_desc_base(s) + sizeof(desc) * s->mac_reg[RDH]; 948 pci_dma_read(d, base, &desc, sizeof(desc)); 949 desc.special = vlan_special; 950 desc.status &= ~E1000_RXD_STAT_DD; 951 if (desc.buffer_addr) { 952 if (desc_offset < size) { 953 size_t iov_copy; 954 hwaddr ba = le64_to_cpu(desc.buffer_addr); 955 size_t copy_size = size - desc_offset; 956 if (copy_size > s->rxbuf_size) { 957 copy_size = s->rxbuf_size; 958 } 959 do { 960 iov_copy = MIN(copy_size, iov->iov_len - iov_ofs); 961 pci_dma_write(d, ba, iov->iov_base + iov_ofs, iov_copy); 962 copy_size -= iov_copy; 963 ba += iov_copy; 964 iov_ofs += iov_copy; 965 if (iov_ofs == iov->iov_len) { 966 iov++; 967 iov_ofs = 0; 968 } 969 } while (copy_size); 970 } 971 desc_offset += desc_size; 972 desc.length = cpu_to_le16(desc_size); 973 if (desc_offset >= total_size) { 974 desc.status |= E1000_RXD_STAT_EOP | E1000_RXD_STAT_IXSM; 975 } else { 976 /* Guest zeroing out status is not a hardware requirement. 977 Clear EOP in case guest didn't do it. */ 978 desc.status &= ~E1000_RXD_STAT_EOP; 979 } 980 } else { // as per intel docs; skip descriptors with null buf addr 981 DBGOUT(RX, "Null RX descriptor!!\n"); 982 } 983 pci_dma_write(d, base, &desc, sizeof(desc)); 984 desc.status |= (vlan_status | E1000_RXD_STAT_DD); 985 pci_dma_write(d, base + offsetof(struct e1000_rx_desc, status), 986 &desc.status, sizeof(desc.status)); 987 988 if (++s->mac_reg[RDH] * sizeof(desc) >= s->mac_reg[RDLEN]) 989 s->mac_reg[RDH] = 0; 990 /* see comment in start_xmit; same here */ 991 if (s->mac_reg[RDH] == rdh_start || 992 rdh_start >= s->mac_reg[RDLEN] / sizeof(desc)) { 993 DBGOUT(RXERR, "RDH wraparound @%x, RDT %x, RDLEN %x\n", 994 rdh_start, s->mac_reg[RDT], s->mac_reg[RDLEN]); 995 e1000_receiver_overrun(s, total_size); 996 return -1; 997 } 998 } while (desc_offset < total_size); 999 1000 e1000x_update_rx_total_stats(s->mac_reg, pkt_type, size, total_size); 1001 1002 n = E1000_ICS_RXT0; 1003 if ((rdt = s->mac_reg[RDT]) < s->mac_reg[RDH]) 1004 rdt += s->mac_reg[RDLEN] / sizeof(desc); 1005 if (((rdt - s->mac_reg[RDH]) * sizeof(desc)) <= s->mac_reg[RDLEN] >> 1006 s->rxbuf_min_shift) 1007 n |= E1000_ICS_RXDMT0; 1008 1009 set_ics(s, 0, n); 1010 1011 return size; 1012 } 1013 1014 static ssize_t 1015 e1000_receive(NetClientState *nc, const uint8_t *buf, size_t size) 1016 { 1017 const struct iovec iov = { 1018 .iov_base = (uint8_t *)buf, 1019 .iov_len = size 1020 }; 1021 1022 return e1000_receive_iov(nc, &iov, 1); 1023 } 1024 1025 static uint32_t 1026 mac_readreg(E1000State *s, int index) 1027 { 1028 return s->mac_reg[index]; 1029 } 1030 1031 static uint32_t 1032 mac_icr_read(E1000State *s, int index) 1033 { 1034 uint32_t ret = s->mac_reg[ICR]; 1035 1036 DBGOUT(INTERRUPT, "ICR read: %x\n", ret); 1037 set_interrupt_cause(s, 0, 0); 1038 return ret; 1039 } 1040 1041 static uint32_t 1042 mac_read_clr4(E1000State *s, int index) 1043 { 1044 uint32_t ret = s->mac_reg[index]; 1045 1046 s->mac_reg[index] = 0; 1047 return ret; 1048 } 1049 1050 static uint32_t 1051 mac_read_clr8(E1000State *s, int index) 1052 { 1053 uint32_t ret = s->mac_reg[index]; 1054 1055 s->mac_reg[index] = 0; 1056 s->mac_reg[index-1] = 0; 1057 return ret; 1058 } 1059 1060 static void 1061 mac_writereg(E1000State *s, int index, uint32_t val) 1062 { 1063 uint32_t macaddr[2]; 1064 1065 s->mac_reg[index] = val; 1066 1067 if (index == RA + 1) { 1068 macaddr[0] = cpu_to_le32(s->mac_reg[RA]); 1069 macaddr[1] = cpu_to_le32(s->mac_reg[RA + 1]); 1070 qemu_format_nic_info_str(qemu_get_queue(s->nic), (uint8_t *)macaddr); 1071 } 1072 } 1073 1074 static void 1075 set_rdt(E1000State *s, int index, uint32_t val) 1076 { 1077 s->mac_reg[index] = val & 0xffff; 1078 if (e1000_has_rxbufs(s, 1)) { 1079 qemu_flush_queued_packets(qemu_get_queue(s->nic)); 1080 } 1081 } 1082 1083 #define LOW_BITS_SET_FUNC(num) \ 1084 static void \ 1085 set_##num##bit(E1000State *s, int index, uint32_t val) \ 1086 { \ 1087 s->mac_reg[index] = val & (BIT(num) - 1); \ 1088 } 1089 1090 LOW_BITS_SET_FUNC(4) 1091 LOW_BITS_SET_FUNC(11) 1092 LOW_BITS_SET_FUNC(13) 1093 LOW_BITS_SET_FUNC(16) 1094 1095 static void 1096 set_dlen(E1000State *s, int index, uint32_t val) 1097 { 1098 s->mac_reg[index] = val & 0xfff80; 1099 } 1100 1101 static void 1102 set_tctl(E1000State *s, int index, uint32_t val) 1103 { 1104 s->mac_reg[index] = val; 1105 s->mac_reg[TDT] &= 0xffff; 1106 start_xmit(s); 1107 } 1108 1109 static void 1110 set_icr(E1000State *s, int index, uint32_t val) 1111 { 1112 DBGOUT(INTERRUPT, "set_icr %x\n", val); 1113 set_interrupt_cause(s, 0, s->mac_reg[ICR] & ~val); 1114 } 1115 1116 static void 1117 set_imc(E1000State *s, int index, uint32_t val) 1118 { 1119 s->mac_reg[IMS] &= ~val; 1120 set_ics(s, 0, 0); 1121 } 1122 1123 static void 1124 set_ims(E1000State *s, int index, uint32_t val) 1125 { 1126 s->mac_reg[IMS] |= val; 1127 set_ics(s, 0, 0); 1128 } 1129 1130 #define getreg(x) [x] = mac_readreg 1131 typedef uint32_t (*readops)(E1000State *, int); 1132 static const readops macreg_readops[] = { 1133 getreg(PBA), getreg(RCTL), getreg(TDH), getreg(TXDCTL), 1134 getreg(WUFC), getreg(TDT), getreg(CTRL), getreg(LEDCTL), 1135 getreg(MANC), getreg(MDIC), getreg(SWSM), getreg(STATUS), 1136 getreg(TORL), getreg(TOTL), getreg(IMS), getreg(TCTL), 1137 getreg(RDH), getreg(RDT), getreg(VET), getreg(ICS), 1138 getreg(TDBAL), getreg(TDBAH), getreg(RDBAH), getreg(RDBAL), 1139 getreg(TDLEN), getreg(RDLEN), getreg(RDTR), getreg(RADV), 1140 getreg(TADV), getreg(ITR), getreg(FCRUC), getreg(IPAV), 1141 getreg(WUC), getreg(WUS), getreg(SCC), getreg(ECOL), 1142 getreg(MCC), getreg(LATECOL), getreg(COLC), getreg(DC), 1143 getreg(TNCRS), getreg(SEQEC), getreg(CEXTERR), getreg(RLEC), 1144 getreg(XONRXC), getreg(XONTXC), getreg(XOFFRXC), getreg(XOFFTXC), 1145 getreg(RFC), getreg(RJC), getreg(RNBC), getreg(TSCTFC), 1146 getreg(MGTPRC), getreg(MGTPDC), getreg(MGTPTC), getreg(GORCL), 1147 getreg(GOTCL), getreg(RDFH), getreg(RDFT), getreg(RDFHS), 1148 getreg(RDFTS), getreg(RDFPC), getreg(TDFH), getreg(TDFT), 1149 getreg(TDFHS), getreg(TDFTS), getreg(TDFPC), getreg(AIT), 1150 1151 [TOTH] = mac_read_clr8, [TORH] = mac_read_clr8, 1152 [GOTCH] = mac_read_clr8, [GORCH] = mac_read_clr8, 1153 [PRC64] = mac_read_clr4, [PRC127] = mac_read_clr4, 1154 [PRC255] = mac_read_clr4, [PRC511] = mac_read_clr4, 1155 [PRC1023] = mac_read_clr4, [PRC1522] = mac_read_clr4, 1156 [PTC64] = mac_read_clr4, [PTC127] = mac_read_clr4, 1157 [PTC255] = mac_read_clr4, [PTC511] = mac_read_clr4, 1158 [PTC1023] = mac_read_clr4, [PTC1522] = mac_read_clr4, 1159 [GPRC] = mac_read_clr4, [GPTC] = mac_read_clr4, 1160 [TPT] = mac_read_clr4, [TPR] = mac_read_clr4, 1161 [RUC] = mac_read_clr4, [ROC] = mac_read_clr4, 1162 [BPRC] = mac_read_clr4, [MPRC] = mac_read_clr4, 1163 [TSCTC] = mac_read_clr4, [BPTC] = mac_read_clr4, 1164 [MPTC] = mac_read_clr4, 1165 [ICR] = mac_icr_read, [EECD] = get_eecd, 1166 [EERD] = flash_eerd_read, 1167 1168 [CRCERRS ... MPC] = &mac_readreg, 1169 [IP6AT ... IP6AT + 3] = &mac_readreg, [IP4AT ... IP4AT + 6] = &mac_readreg, 1170 [FFLT ... FFLT + 6] = &mac_readreg, 1171 [RA ... RA + 31] = &mac_readreg, 1172 [WUPM ... WUPM + 31] = &mac_readreg, 1173 [MTA ... MTA + E1000_MC_TBL_SIZE - 1] = &mac_readreg, 1174 [VFTA ... VFTA + E1000_VLAN_FILTER_TBL_SIZE - 1] = &mac_readreg, 1175 [FFMT ... FFMT + 254] = &mac_readreg, 1176 [FFVT ... FFVT + 254] = &mac_readreg, 1177 [PBM ... PBM + 16383] = &mac_readreg, 1178 }; 1179 enum { NREADOPS = ARRAY_SIZE(macreg_readops) }; 1180 1181 #define putreg(x) [x] = mac_writereg 1182 typedef void (*writeops)(E1000State *, int, uint32_t); 1183 static const writeops macreg_writeops[] = { 1184 putreg(PBA), putreg(EERD), putreg(SWSM), putreg(WUFC), 1185 putreg(TDBAL), putreg(TDBAH), putreg(TXDCTL), putreg(RDBAH), 1186 putreg(RDBAL), putreg(LEDCTL), putreg(VET), putreg(FCRUC), 1187 putreg(IPAV), putreg(WUC), 1188 putreg(WUS), 1189 1190 [TDLEN] = set_dlen, [RDLEN] = set_dlen, [TCTL] = set_tctl, 1191 [TDT] = set_tctl, [MDIC] = set_mdic, [ICS] = set_ics, 1192 [TDH] = set_16bit, [RDH] = set_16bit, [RDT] = set_rdt, 1193 [IMC] = set_imc, [IMS] = set_ims, [ICR] = set_icr, 1194 [EECD] = set_eecd, [RCTL] = set_rx_control, [CTRL] = set_ctrl, 1195 [RDTR] = set_16bit, [RADV] = set_16bit, [TADV] = set_16bit, 1196 [ITR] = set_16bit, [TDFH] = set_11bit, [TDFT] = set_11bit, 1197 [TDFHS] = set_13bit, [TDFTS] = set_13bit, [TDFPC] = set_13bit, 1198 [RDFH] = set_13bit, [RDFT] = set_13bit, [RDFHS] = set_13bit, 1199 [RDFTS] = set_13bit, [RDFPC] = set_13bit, [AIT] = set_16bit, 1200 1201 [IP6AT ... IP6AT + 3] = &mac_writereg, [IP4AT ... IP4AT + 6] = &mac_writereg, 1202 [FFLT ... FFLT + 6] = &set_11bit, 1203 [RA ... RA + 31] = &mac_writereg, 1204 [WUPM ... WUPM + 31] = &mac_writereg, 1205 [MTA ... MTA + E1000_MC_TBL_SIZE - 1] = &mac_writereg, 1206 [VFTA ... VFTA + E1000_VLAN_FILTER_TBL_SIZE - 1] = &mac_writereg, 1207 [FFMT ... FFMT + 254] = &set_4bit, [FFVT ... FFVT + 254] = &mac_writereg, 1208 [PBM ... PBM + 16383] = &mac_writereg, 1209 }; 1210 1211 enum { NWRITEOPS = ARRAY_SIZE(macreg_writeops) }; 1212 1213 enum { MAC_ACCESS_PARTIAL = 1, MAC_ACCESS_FLAG_NEEDED = 2 }; 1214 1215 #define markflag(x) ((E1000_FLAG_##x << 2) | MAC_ACCESS_FLAG_NEEDED) 1216 /* In the array below the meaning of the bits is: [f|f|f|f|f|f|n|p] 1217 * f - flag bits (up to 6 possible flags) 1218 * n - flag needed 1219 * p - partially implenented */ 1220 static const uint8_t mac_reg_access[0x8000] = { 1221 [IPAV] = markflag(MAC), [WUC] = markflag(MAC), 1222 [IP6AT] = markflag(MAC), [IP4AT] = markflag(MAC), 1223 [FFVT] = markflag(MAC), [WUPM] = markflag(MAC), 1224 [ECOL] = markflag(MAC), [MCC] = markflag(MAC), 1225 [DC] = markflag(MAC), [TNCRS] = markflag(MAC), 1226 [RLEC] = markflag(MAC), [XONRXC] = markflag(MAC), 1227 [XOFFTXC] = markflag(MAC), [RFC] = markflag(MAC), 1228 [TSCTFC] = markflag(MAC), [MGTPRC] = markflag(MAC), 1229 [WUS] = markflag(MAC), [AIT] = markflag(MAC), 1230 [FFLT] = markflag(MAC), [FFMT] = markflag(MAC), 1231 [SCC] = markflag(MAC), [FCRUC] = markflag(MAC), 1232 [LATECOL] = markflag(MAC), [COLC] = markflag(MAC), 1233 [SEQEC] = markflag(MAC), [CEXTERR] = markflag(MAC), 1234 [XONTXC] = markflag(MAC), [XOFFRXC] = markflag(MAC), 1235 [RJC] = markflag(MAC), [RNBC] = markflag(MAC), 1236 [MGTPDC] = markflag(MAC), [MGTPTC] = markflag(MAC), 1237 [RUC] = markflag(MAC), [ROC] = markflag(MAC), 1238 [GORCL] = markflag(MAC), [GORCH] = markflag(MAC), 1239 [GOTCL] = markflag(MAC), [GOTCH] = markflag(MAC), 1240 [BPRC] = markflag(MAC), [MPRC] = markflag(MAC), 1241 [TSCTC] = markflag(MAC), [PRC64] = markflag(MAC), 1242 [PRC127] = markflag(MAC), [PRC255] = markflag(MAC), 1243 [PRC511] = markflag(MAC), [PRC1023] = markflag(MAC), 1244 [PRC1522] = markflag(MAC), [PTC64] = markflag(MAC), 1245 [PTC127] = markflag(MAC), [PTC255] = markflag(MAC), 1246 [PTC511] = markflag(MAC), [PTC1023] = markflag(MAC), 1247 [PTC1522] = markflag(MAC), [MPTC] = markflag(MAC), 1248 [BPTC] = markflag(MAC), 1249 1250 [TDFH] = markflag(MAC) | MAC_ACCESS_PARTIAL, 1251 [TDFT] = markflag(MAC) | MAC_ACCESS_PARTIAL, 1252 [TDFHS] = markflag(MAC) | MAC_ACCESS_PARTIAL, 1253 [TDFTS] = markflag(MAC) | MAC_ACCESS_PARTIAL, 1254 [TDFPC] = markflag(MAC) | MAC_ACCESS_PARTIAL, 1255 [RDFH] = markflag(MAC) | MAC_ACCESS_PARTIAL, 1256 [RDFT] = markflag(MAC) | MAC_ACCESS_PARTIAL, 1257 [RDFHS] = markflag(MAC) | MAC_ACCESS_PARTIAL, 1258 [RDFTS] = markflag(MAC) | MAC_ACCESS_PARTIAL, 1259 [RDFPC] = markflag(MAC) | MAC_ACCESS_PARTIAL, 1260 [PBM] = markflag(MAC) | MAC_ACCESS_PARTIAL, 1261 }; 1262 1263 static void 1264 e1000_mmio_write(void *opaque, hwaddr addr, uint64_t val, 1265 unsigned size) 1266 { 1267 E1000State *s = opaque; 1268 unsigned int index = (addr & 0x1ffff) >> 2; 1269 1270 if (index < NWRITEOPS && macreg_writeops[index]) { 1271 if (!(mac_reg_access[index] & MAC_ACCESS_FLAG_NEEDED) 1272 || (s->compat_flags & (mac_reg_access[index] >> 2))) { 1273 if (mac_reg_access[index] & MAC_ACCESS_PARTIAL) { 1274 DBGOUT(GENERAL, "Writing to register at offset: 0x%08x. " 1275 "It is not fully implemented.\n", index<<2); 1276 } 1277 macreg_writeops[index](s, index, val); 1278 } else { /* "flag needed" bit is set, but the flag is not active */ 1279 DBGOUT(MMIO, "MMIO write attempt to disabled reg. addr=0x%08x\n", 1280 index<<2); 1281 } 1282 } else if (index < NREADOPS && macreg_readops[index]) { 1283 DBGOUT(MMIO, "e1000_mmio_writel RO %x: 0x%04"PRIx64"\n", 1284 index<<2, val); 1285 } else { 1286 DBGOUT(UNKNOWN, "MMIO unknown write addr=0x%08x,val=0x%08"PRIx64"\n", 1287 index<<2, val); 1288 } 1289 } 1290 1291 static uint64_t 1292 e1000_mmio_read(void *opaque, hwaddr addr, unsigned size) 1293 { 1294 E1000State *s = opaque; 1295 unsigned int index = (addr & 0x1ffff) >> 2; 1296 1297 if (index < NREADOPS && macreg_readops[index]) { 1298 if (!(mac_reg_access[index] & MAC_ACCESS_FLAG_NEEDED) 1299 || (s->compat_flags & (mac_reg_access[index] >> 2))) { 1300 if (mac_reg_access[index] & MAC_ACCESS_PARTIAL) { 1301 DBGOUT(GENERAL, "Reading register at offset: 0x%08x. " 1302 "It is not fully implemented.\n", index<<2); 1303 } 1304 return macreg_readops[index](s, index); 1305 } else { /* "flag needed" bit is set, but the flag is not active */ 1306 DBGOUT(MMIO, "MMIO read attempt of disabled reg. addr=0x%08x\n", 1307 index<<2); 1308 } 1309 } else { 1310 DBGOUT(UNKNOWN, "MMIO unknown read addr=0x%08x\n", index<<2); 1311 } 1312 return 0; 1313 } 1314 1315 static const MemoryRegionOps e1000_mmio_ops = { 1316 .read = e1000_mmio_read, 1317 .write = e1000_mmio_write, 1318 .endianness = DEVICE_LITTLE_ENDIAN, 1319 .impl = { 1320 .min_access_size = 4, 1321 .max_access_size = 4, 1322 }, 1323 }; 1324 1325 static uint64_t e1000_io_read(void *opaque, hwaddr addr, 1326 unsigned size) 1327 { 1328 E1000State *s = opaque; 1329 1330 (void)s; 1331 return 0; 1332 } 1333 1334 static void e1000_io_write(void *opaque, hwaddr addr, 1335 uint64_t val, unsigned size) 1336 { 1337 E1000State *s = opaque; 1338 1339 (void)s; 1340 } 1341 1342 static const MemoryRegionOps e1000_io_ops = { 1343 .read = e1000_io_read, 1344 .write = e1000_io_write, 1345 .endianness = DEVICE_LITTLE_ENDIAN, 1346 }; 1347 1348 static bool is_version_1(void *opaque, int version_id) 1349 { 1350 return version_id == 1; 1351 } 1352 1353 static int e1000_pre_save(void *opaque) 1354 { 1355 E1000State *s = opaque; 1356 NetClientState *nc = qemu_get_queue(s->nic); 1357 1358 /* 1359 * If link is down and auto-negotiation is supported and ongoing, 1360 * complete auto-negotiation immediately. This allows us to look 1361 * at MII_BMSR_AN_COMP to infer link status on load. 1362 */ 1363 if (nc->link_down && have_autoneg(s)) { 1364 s->phy_reg[MII_BMSR] |= MII_BMSR_AN_COMP; 1365 } 1366 1367 /* Decide which set of props to migrate in the main structure */ 1368 if (chkflag(TSO) || !s->use_tso_for_migration) { 1369 /* Either we're migrating with the extra subsection, in which 1370 * case the mig_props is always 'props' OR 1371 * we've not got the subsection, but 'props' was the last 1372 * updated. 1373 */ 1374 s->mig_props = s->tx.props; 1375 } else { 1376 /* We're not using the subsection, and 'tso_props' was 1377 * the last updated. 1378 */ 1379 s->mig_props = s->tx.tso_props; 1380 } 1381 return 0; 1382 } 1383 1384 static int e1000_post_load(void *opaque, int version_id) 1385 { 1386 E1000State *s = opaque; 1387 NetClientState *nc = qemu_get_queue(s->nic); 1388 1389 s->mit_ide = 0; 1390 s->mit_timer_on = true; 1391 timer_mod(s->mit_timer, qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL) + 1); 1392 1393 /* nc.link_down can't be migrated, so infer link_down according 1394 * to link status bit in mac_reg[STATUS]. 1395 * Alternatively, restart link negotiation if it was in progress. */ 1396 nc->link_down = (s->mac_reg[STATUS] & E1000_STATUS_LU) == 0; 1397 1398 if (have_autoneg(s) && !(s->phy_reg[MII_BMSR] & MII_BMSR_AN_COMP)) { 1399 nc->link_down = false; 1400 timer_mod(s->autoneg_timer, 1401 qemu_clock_get_ms(QEMU_CLOCK_VIRTUAL) + 500); 1402 } 1403 1404 s->tx.props = s->mig_props; 1405 if (!s->received_tx_tso) { 1406 /* We received only one set of offload data (tx.props) 1407 * and haven't got tx.tso_props. The best we can do 1408 * is dupe the data. 1409 */ 1410 s->tx.tso_props = s->mig_props; 1411 } 1412 return 0; 1413 } 1414 1415 static int e1000_tx_tso_post_load(void *opaque, int version_id) 1416 { 1417 E1000State *s = opaque; 1418 s->received_tx_tso = true; 1419 return 0; 1420 } 1421 1422 static bool e1000_full_mac_needed(void *opaque) 1423 { 1424 E1000State *s = opaque; 1425 1426 return chkflag(MAC); 1427 } 1428 1429 static bool e1000_tso_state_needed(void *opaque) 1430 { 1431 E1000State *s = opaque; 1432 1433 return chkflag(TSO); 1434 } 1435 1436 static const VMStateDescription vmstate_e1000_mit_state = { 1437 .name = "e1000/mit_state", 1438 .version_id = 1, 1439 .minimum_version_id = 1, 1440 .fields = (const VMStateField[]) { 1441 VMSTATE_UINT32(mac_reg[RDTR], E1000State), 1442 VMSTATE_UINT32(mac_reg[RADV], E1000State), 1443 VMSTATE_UINT32(mac_reg[TADV], E1000State), 1444 VMSTATE_UINT32(mac_reg[ITR], E1000State), 1445 VMSTATE_BOOL(mit_irq_level, E1000State), 1446 VMSTATE_END_OF_LIST() 1447 } 1448 }; 1449 1450 static const VMStateDescription vmstate_e1000_full_mac_state = { 1451 .name = "e1000/full_mac_state", 1452 .version_id = 1, 1453 .minimum_version_id = 1, 1454 .needed = e1000_full_mac_needed, 1455 .fields = (const VMStateField[]) { 1456 VMSTATE_UINT32_ARRAY(mac_reg, E1000State, 0x8000), 1457 VMSTATE_END_OF_LIST() 1458 } 1459 }; 1460 1461 static const VMStateDescription vmstate_e1000_tx_tso_state = { 1462 .name = "e1000/tx_tso_state", 1463 .version_id = 1, 1464 .minimum_version_id = 1, 1465 .needed = e1000_tso_state_needed, 1466 .post_load = e1000_tx_tso_post_load, 1467 .fields = (const VMStateField[]) { 1468 VMSTATE_UINT8(tx.tso_props.ipcss, E1000State), 1469 VMSTATE_UINT8(tx.tso_props.ipcso, E1000State), 1470 VMSTATE_UINT16(tx.tso_props.ipcse, E1000State), 1471 VMSTATE_UINT8(tx.tso_props.tucss, E1000State), 1472 VMSTATE_UINT8(tx.tso_props.tucso, E1000State), 1473 VMSTATE_UINT16(tx.tso_props.tucse, E1000State), 1474 VMSTATE_UINT32(tx.tso_props.paylen, E1000State), 1475 VMSTATE_UINT8(tx.tso_props.hdr_len, E1000State), 1476 VMSTATE_UINT16(tx.tso_props.mss, E1000State), 1477 VMSTATE_INT8(tx.tso_props.ip, E1000State), 1478 VMSTATE_INT8(tx.tso_props.tcp, E1000State), 1479 VMSTATE_END_OF_LIST() 1480 } 1481 }; 1482 1483 static const VMStateDescription vmstate_e1000 = { 1484 .name = "e1000", 1485 .version_id = 2, 1486 .minimum_version_id = 1, 1487 .pre_save = e1000_pre_save, 1488 .post_load = e1000_post_load, 1489 .fields = (const VMStateField[]) { 1490 VMSTATE_PCI_DEVICE(parent_obj, E1000State), 1491 VMSTATE_UNUSED_TEST(is_version_1, 4), /* was instance id */ 1492 VMSTATE_UNUSED(4), /* Was mmio_base. */ 1493 VMSTATE_UINT32(rxbuf_size, E1000State), 1494 VMSTATE_UINT32(rxbuf_min_shift, E1000State), 1495 VMSTATE_UINT32(eecd_state.val_in, E1000State), 1496 VMSTATE_UINT16(eecd_state.bitnum_in, E1000State), 1497 VMSTATE_UINT16(eecd_state.bitnum_out, E1000State), 1498 VMSTATE_UINT16(eecd_state.reading, E1000State), 1499 VMSTATE_UINT32(eecd_state.old_eecd, E1000State), 1500 VMSTATE_UINT8(mig_props.ipcss, E1000State), 1501 VMSTATE_UINT8(mig_props.ipcso, E1000State), 1502 VMSTATE_UINT16(mig_props.ipcse, E1000State), 1503 VMSTATE_UINT8(mig_props.tucss, E1000State), 1504 VMSTATE_UINT8(mig_props.tucso, E1000State), 1505 VMSTATE_UINT16(mig_props.tucse, E1000State), 1506 VMSTATE_UINT32(mig_props.paylen, E1000State), 1507 VMSTATE_UINT8(mig_props.hdr_len, E1000State), 1508 VMSTATE_UINT16(mig_props.mss, E1000State), 1509 VMSTATE_UINT16(tx.size, E1000State), 1510 VMSTATE_UINT16(tx.tso_frames, E1000State), 1511 VMSTATE_UINT8(tx.sum_needed, E1000State), 1512 VMSTATE_INT8(mig_props.ip, E1000State), 1513 VMSTATE_INT8(mig_props.tcp, E1000State), 1514 VMSTATE_BUFFER(tx.header, E1000State), 1515 VMSTATE_BUFFER(tx.data, E1000State), 1516 VMSTATE_UINT16_ARRAY(eeprom_data, E1000State, 64), 1517 VMSTATE_UINT16_ARRAY(phy_reg, E1000State, 0x20), 1518 VMSTATE_UINT32(mac_reg[CTRL], E1000State), 1519 VMSTATE_UINT32(mac_reg[EECD], E1000State), 1520 VMSTATE_UINT32(mac_reg[EERD], E1000State), 1521 VMSTATE_UINT32(mac_reg[GPRC], E1000State), 1522 VMSTATE_UINT32(mac_reg[GPTC], E1000State), 1523 VMSTATE_UINT32(mac_reg[ICR], E1000State), 1524 VMSTATE_UINT32(mac_reg[ICS], E1000State), 1525 VMSTATE_UINT32(mac_reg[IMC], E1000State), 1526 VMSTATE_UINT32(mac_reg[IMS], E1000State), 1527 VMSTATE_UINT32(mac_reg[LEDCTL], E1000State), 1528 VMSTATE_UINT32(mac_reg[MANC], E1000State), 1529 VMSTATE_UINT32(mac_reg[MDIC], E1000State), 1530 VMSTATE_UINT32(mac_reg[MPC], E1000State), 1531 VMSTATE_UINT32(mac_reg[PBA], E1000State), 1532 VMSTATE_UINT32(mac_reg[RCTL], E1000State), 1533 VMSTATE_UINT32(mac_reg[RDBAH], E1000State), 1534 VMSTATE_UINT32(mac_reg[RDBAL], E1000State), 1535 VMSTATE_UINT32(mac_reg[RDH], E1000State), 1536 VMSTATE_UINT32(mac_reg[RDLEN], E1000State), 1537 VMSTATE_UINT32(mac_reg[RDT], E1000State), 1538 VMSTATE_UINT32(mac_reg[STATUS], E1000State), 1539 VMSTATE_UINT32(mac_reg[SWSM], E1000State), 1540 VMSTATE_UINT32(mac_reg[TCTL], E1000State), 1541 VMSTATE_UINT32(mac_reg[TDBAH], E1000State), 1542 VMSTATE_UINT32(mac_reg[TDBAL], E1000State), 1543 VMSTATE_UINT32(mac_reg[TDH], E1000State), 1544 VMSTATE_UINT32(mac_reg[TDLEN], E1000State), 1545 VMSTATE_UINT32(mac_reg[TDT], E1000State), 1546 VMSTATE_UINT32(mac_reg[TORH], E1000State), 1547 VMSTATE_UINT32(mac_reg[TORL], E1000State), 1548 VMSTATE_UINT32(mac_reg[TOTH], E1000State), 1549 VMSTATE_UINT32(mac_reg[TOTL], E1000State), 1550 VMSTATE_UINT32(mac_reg[TPR], E1000State), 1551 VMSTATE_UINT32(mac_reg[TPT], E1000State), 1552 VMSTATE_UINT32(mac_reg[TXDCTL], E1000State), 1553 VMSTATE_UINT32(mac_reg[WUFC], E1000State), 1554 VMSTATE_UINT32(mac_reg[VET], E1000State), 1555 VMSTATE_UINT32_SUB_ARRAY(mac_reg, E1000State, RA, 32), 1556 VMSTATE_UINT32_SUB_ARRAY(mac_reg, E1000State, MTA, E1000_MC_TBL_SIZE), 1557 VMSTATE_UINT32_SUB_ARRAY(mac_reg, E1000State, VFTA, 1558 E1000_VLAN_FILTER_TBL_SIZE), 1559 VMSTATE_END_OF_LIST() 1560 }, 1561 .subsections = (const VMStateDescription * const []) { 1562 &vmstate_e1000_mit_state, 1563 &vmstate_e1000_full_mac_state, 1564 &vmstate_e1000_tx_tso_state, 1565 NULL 1566 } 1567 }; 1568 1569 /* 1570 * EEPROM contents documented in Tables 5-2 and 5-3, pp. 98-102. 1571 * Note: A valid DevId will be inserted during pci_e1000_realize(). 1572 */ 1573 static const uint16_t e1000_eeprom_template[64] = { 1574 0x0000, 0x0000, 0x0000, 0x0000, 0xffff, 0x0000, 0x0000, 0x0000, 1575 0x3000, 0x1000, 0x6403, 0 /*DevId*/, 0x8086, 0 /*DevId*/, 0x8086, 0x3040, 1576 0x0008, 0x2000, 0x7e14, 0x0048, 0x1000, 0x00d8, 0x0000, 0x2700, 1577 0x6cc9, 0x3150, 0x0722, 0x040b, 0x0984, 0x0000, 0xc000, 0x0706, 1578 0x1008, 0x0000, 0x0f04, 0x7fff, 0x4d01, 0xffff, 0xffff, 0xffff, 1579 0xffff, 0xffff, 0xffff, 0xffff, 0xffff, 0xffff, 0xffff, 0xffff, 1580 0x0100, 0x4000, 0x121c, 0xffff, 0xffff, 0xffff, 0xffff, 0xffff, 1581 0xffff, 0xffff, 0xffff, 0xffff, 0xffff, 0xffff, 0xffff, 0x0000, 1582 }; 1583 1584 /* PCI interface */ 1585 1586 static void 1587 e1000_mmio_setup(E1000State *d) 1588 { 1589 int i; 1590 const uint32_t excluded_regs[] = { 1591 E1000_MDIC, E1000_ICR, E1000_ICS, E1000_IMS, 1592 E1000_IMC, E1000_TCTL, E1000_TDT, PNPMMIO_SIZE 1593 }; 1594 1595 memory_region_init_io(&d->mmio, OBJECT(d), &e1000_mmio_ops, d, 1596 "e1000-mmio", PNPMMIO_SIZE); 1597 memory_region_add_coalescing(&d->mmio, 0, excluded_regs[0]); 1598 for (i = 0; excluded_regs[i] != PNPMMIO_SIZE; i++) 1599 memory_region_add_coalescing(&d->mmio, excluded_regs[i] + 4, 1600 excluded_regs[i+1] - excluded_regs[i] - 4); 1601 memory_region_init_io(&d->io, OBJECT(d), &e1000_io_ops, d, "e1000-io", IOPORT_SIZE); 1602 } 1603 1604 static void 1605 pci_e1000_uninit(PCIDevice *dev) 1606 { 1607 E1000State *d = E1000(dev); 1608 1609 timer_free(d->autoneg_timer); 1610 timer_free(d->mit_timer); 1611 timer_free(d->flush_queue_timer); 1612 qemu_del_nic(d->nic); 1613 } 1614 1615 static NetClientInfo net_e1000_info = { 1616 .type = NET_CLIENT_DRIVER_NIC, 1617 .size = sizeof(NICState), 1618 .can_receive = e1000_can_receive, 1619 .receive = e1000_receive, 1620 .receive_iov = e1000_receive_iov, 1621 .link_status_changed = e1000_set_link_status, 1622 }; 1623 1624 static void e1000_write_config(PCIDevice *pci_dev, uint32_t address, 1625 uint32_t val, int len) 1626 { 1627 E1000State *s = E1000(pci_dev); 1628 1629 pci_default_write_config(pci_dev, address, val, len); 1630 1631 if (range_covers_byte(address, len, PCI_COMMAND) && 1632 (pci_dev->config[PCI_COMMAND] & PCI_COMMAND_MASTER)) { 1633 qemu_flush_queued_packets(qemu_get_queue(s->nic)); 1634 } 1635 } 1636 1637 static void pci_e1000_realize(PCIDevice *pci_dev, Error **errp) 1638 { 1639 DeviceState *dev = DEVICE(pci_dev); 1640 E1000State *d = E1000(pci_dev); 1641 uint8_t *pci_conf; 1642 uint8_t *macaddr; 1643 1644 pci_dev->config_write = e1000_write_config; 1645 1646 pci_conf = pci_dev->config; 1647 1648 /* TODO: RST# value should be 0, PCI spec 6.2.4 */ 1649 pci_conf[PCI_CACHE_LINE_SIZE] = 0x10; 1650 1651 pci_conf[PCI_INTERRUPT_PIN] = 1; /* interrupt pin A */ 1652 1653 e1000_mmio_setup(d); 1654 1655 pci_register_bar(pci_dev, 0, PCI_BASE_ADDRESS_SPACE_MEMORY, &d->mmio); 1656 1657 pci_register_bar(pci_dev, 1, PCI_BASE_ADDRESS_SPACE_IO, &d->io); 1658 1659 qemu_macaddr_default_if_unset(&d->conf.macaddr); 1660 macaddr = d->conf.macaddr.a; 1661 1662 e1000x_core_prepare_eeprom(d->eeprom_data, 1663 e1000_eeprom_template, 1664 sizeof(e1000_eeprom_template), 1665 PCI_DEVICE_GET_CLASS(pci_dev)->device_id, 1666 macaddr); 1667 1668 d->nic = qemu_new_nic(&net_e1000_info, &d->conf, 1669 object_get_typename(OBJECT(d)), dev->id, 1670 &dev->mem_reentrancy_guard, d); 1671 1672 qemu_format_nic_info_str(qemu_get_queue(d->nic), macaddr); 1673 1674 d->autoneg_timer = timer_new_ms(QEMU_CLOCK_VIRTUAL, e1000_autoneg_timer, d); 1675 d->mit_timer = timer_new_ns(QEMU_CLOCK_VIRTUAL, e1000_mit_timer, d); 1676 d->flush_queue_timer = timer_new_ms(QEMU_CLOCK_VIRTUAL, 1677 e1000_flush_queue_timer, d); 1678 } 1679 1680 static Property e1000_properties[] = { 1681 DEFINE_NIC_PROPERTIES(E1000State, conf), 1682 DEFINE_PROP_BIT("extra_mac_registers", E1000State, 1683 compat_flags, E1000_FLAG_MAC_BIT, true), 1684 DEFINE_PROP_BIT("migrate_tso_props", E1000State, 1685 compat_flags, E1000_FLAG_TSO_BIT, true), 1686 DEFINE_PROP_BIT("init-vet", E1000State, 1687 compat_flags, E1000_FLAG_VET_BIT, true), 1688 DEFINE_PROP_END_OF_LIST(), 1689 }; 1690 1691 typedef struct E1000Info { 1692 const char *name; 1693 uint16_t device_id; 1694 uint8_t revision; 1695 uint16_t phy_id2; 1696 } E1000Info; 1697 1698 static void e1000_class_init(ObjectClass *klass, void *data) 1699 { 1700 DeviceClass *dc = DEVICE_CLASS(klass); 1701 ResettableClass *rc = RESETTABLE_CLASS(klass); 1702 PCIDeviceClass *k = PCI_DEVICE_CLASS(klass); 1703 E1000BaseClass *e = E1000_CLASS(klass); 1704 const E1000Info *info = data; 1705 1706 k->realize = pci_e1000_realize; 1707 k->exit = pci_e1000_uninit; 1708 k->romfile = "efi-e1000.rom"; 1709 k->vendor_id = PCI_VENDOR_ID_INTEL; 1710 k->device_id = info->device_id; 1711 k->revision = info->revision; 1712 e->phy_id2 = info->phy_id2; 1713 k->class_id = PCI_CLASS_NETWORK_ETHERNET; 1714 rc->phases.hold = e1000_reset_hold; 1715 set_bit(DEVICE_CATEGORY_NETWORK, dc->categories); 1716 dc->desc = "Intel Gigabit Ethernet"; 1717 dc->vmsd = &vmstate_e1000; 1718 device_class_set_props(dc, e1000_properties); 1719 } 1720 1721 static void e1000_instance_init(Object *obj) 1722 { 1723 E1000State *n = E1000(obj); 1724 device_add_bootindex_property(obj, &n->conf.bootindex, 1725 "bootindex", "/ethernet-phy@0", 1726 DEVICE(n)); 1727 } 1728 1729 static const TypeInfo e1000_base_info = { 1730 .name = TYPE_E1000_BASE, 1731 .parent = TYPE_PCI_DEVICE, 1732 .instance_size = sizeof(E1000State), 1733 .instance_init = e1000_instance_init, 1734 .class_size = sizeof(E1000BaseClass), 1735 .abstract = true, 1736 .interfaces = (InterfaceInfo[]) { 1737 { INTERFACE_CONVENTIONAL_PCI_DEVICE }, 1738 { }, 1739 }, 1740 }; 1741 1742 static const E1000Info e1000_devices[] = { 1743 { 1744 .name = "e1000", 1745 .device_id = E1000_DEV_ID_82540EM, 1746 .revision = 0x03, 1747 .phy_id2 = E1000_PHY_ID2_8254xx_DEFAULT, 1748 }, 1749 { 1750 .name = "e1000-82544gc", 1751 .device_id = E1000_DEV_ID_82544GC_COPPER, 1752 .revision = 0x03, 1753 .phy_id2 = E1000_PHY_ID2_82544x, 1754 }, 1755 { 1756 .name = "e1000-82545em", 1757 .device_id = E1000_DEV_ID_82545EM_COPPER, 1758 .revision = 0x03, 1759 .phy_id2 = E1000_PHY_ID2_8254xx_DEFAULT, 1760 }, 1761 }; 1762 1763 static void e1000_register_types(void) 1764 { 1765 int i; 1766 1767 type_register_static(&e1000_base_info); 1768 for (i = 0; i < ARRAY_SIZE(e1000_devices); i++) { 1769 const E1000Info *info = &e1000_devices[i]; 1770 TypeInfo type_info = {}; 1771 1772 type_info.name = info->name; 1773 type_info.parent = TYPE_E1000_BASE; 1774 type_info.class_data = (void *)info; 1775 type_info.class_init = e1000_class_init; 1776 1777 type_register(&type_info); 1778 } 1779 } 1780 1781 type_init(e1000_register_types) 1782