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kernel / drivers / staging / et131x / et131x.c
at v3.6-rc2 5444 lines 160 kB view raw
1/* 2 * Agere Systems Inc. 3 * 10/100/1000 Base-T Ethernet Driver for the ET1301 and ET131x series MACs 4 * 5 * Copyright © 2005 Agere Systems Inc. 6 * All rights reserved. 7 * http://www.agere.com 8 * 9 * Copyright (c) 2011 Mark Einon <mark.einon@gmail.com> 10 * 11 *------------------------------------------------------------------------------ 12 * 13 * SOFTWARE LICENSE 14 * 15 * This software is provided subject to the following terms and conditions, 16 * which you should read carefully before using the software. Using this 17 * software indicates your acceptance of these terms and conditions. If you do 18 * not agree with these terms and conditions, do not use the software. 19 * 20 * Copyright © 2005 Agere Systems Inc. 21 * All rights reserved. 22 * 23 * Redistribution and use in source or binary forms, with or without 24 * modifications, are permitted provided that the following conditions are met: 25 * 26 * . Redistributions of source code must retain the above copyright notice, this 27 * list of conditions and the following Disclaimer as comments in the code as 28 * well as in the documentation and/or other materials provided with the 29 * distribution. 30 * 31 * . Redistributions in binary form must reproduce the above copyright notice, 32 * this list of conditions and the following Disclaimer in the documentation 33 * and/or other materials provided with the distribution. 34 * 35 * . Neither the name of Agere Systems Inc. nor the names of the contributors 36 * may be used to endorse or promote products derived from this software 37 * without specific prior written permission. 38 * 39 * Disclaimer 40 * 41 * THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, 42 * INCLUDING, BUT NOT LIMITED TO, INFRINGEMENT AND THE IMPLIED WARRANTIES OF 43 * MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. ANY 44 * USE, MODIFICATION OR DISTRIBUTION OF THIS SOFTWARE IS SOLELY AT THE USERS OWN 45 * RISK. IN NO EVENT SHALL AGERE SYSTEMS INC. OR CONTRIBUTORS BE LIABLE FOR ANY 46 * DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES 47 * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; 48 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND 49 * ON ANY THEORY OF LIABILITY, INCLUDING, BUT NOT LIMITED TO, CONTRACT, STRICT 50 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT 51 * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH 52 * DAMAGE. 53 * 54 */ 55 56#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt 57 58#include <linux/pci.h> 59#include <linux/init.h> 60#include <linux/module.h> 61#include <linux/types.h> 62#include <linux/kernel.h> 63 64#include <linux/sched.h> 65#include <linux/ptrace.h> 66#include <linux/slab.h> 67#include <linux/ctype.h> 68#include <linux/string.h> 69#include <linux/timer.h> 70#include <linux/interrupt.h> 71#include <linux/in.h> 72#include <linux/delay.h> 73#include <linux/bitops.h> 74#include <linux/io.h> 75 76#include <linux/netdevice.h> 77#include <linux/etherdevice.h> 78#include <linux/skbuff.h> 79#include <linux/if_arp.h> 80#include <linux/ioport.h> 81#include <linux/crc32.h> 82#include <linux/random.h> 83#include <linux/phy.h> 84 85#include "et131x.h" 86 87MODULE_AUTHOR("Victor Soriano <vjsoriano@agere.com>"); 88MODULE_AUTHOR("Mark Einon <mark.einon@gmail.com>"); 89MODULE_LICENSE("Dual BSD/GPL"); 90MODULE_DESCRIPTION("10/100/1000 Base-T Ethernet Driver for the ET1310 by Agere Systems"); 91 92/* EEPROM defines */ 93#define MAX_NUM_REGISTER_POLLS 1000 94#define MAX_NUM_WRITE_RETRIES 2 95 96/* MAC defines */ 97#define COUNTER_WRAP_16_BIT 0x10000 98#define COUNTER_WRAP_12_BIT 0x1000 99 100/* PCI defines */ 101#define INTERNAL_MEM_SIZE 0x400 /* 1024 of internal memory */ 102#define INTERNAL_MEM_RX_OFFSET 0x1FF /* 50% Tx, 50% Rx */ 103 104/* ISR defines */ 105/* 106 * For interrupts, normal running is: 107 * rxdma_xfr_done, phy_interrupt, mac_stat_interrupt, 108 * watchdog_interrupt & txdma_xfer_done 109 * 110 * In both cases, when flow control is enabled for either Tx or bi-direction, 111 * we additional enable rx_fbr0_low and rx_fbr1_low, so we know when the 112 * buffer rings are running low. 113 */ 114#define INT_MASK_DISABLE 0xffffffff 115 116/* NOTE: Masking out MAC_STAT Interrupt for now... 117 * #define INT_MASK_ENABLE 0xfff6bf17 118 * #define INT_MASK_ENABLE_NO_FLOW 0xfff6bfd7 119 */ 120#define INT_MASK_ENABLE 0xfffebf17 121#define INT_MASK_ENABLE_NO_FLOW 0xfffebfd7 122 123/* General defines */ 124/* Packet and header sizes */ 125#define NIC_MIN_PACKET_SIZE 60 126 127/* Multicast list size */ 128#define NIC_MAX_MCAST_LIST 128 129 130/* Supported Filters */ 131#define ET131X_PACKET_TYPE_DIRECTED 0x0001 132#define ET131X_PACKET_TYPE_MULTICAST 0x0002 133#define ET131X_PACKET_TYPE_BROADCAST 0x0004 134#define ET131X_PACKET_TYPE_PROMISCUOUS 0x0008 135#define ET131X_PACKET_TYPE_ALL_MULTICAST 0x0010 136 137/* Tx Timeout */ 138#define ET131X_TX_TIMEOUT (1 * HZ) 139#define NIC_SEND_HANG_THRESHOLD 0 140 141/* MP_TCB flags */ 142#define fMP_DEST_MULTI 0x00000001 143#define fMP_DEST_BROAD 0x00000002 144 145/* MP_ADAPTER flags */ 146#define fMP_ADAPTER_RECV_LOOKASIDE 0x00000004 147#define fMP_ADAPTER_INTERRUPT_IN_USE 0x00000008 148 149/* MP_SHARED flags */ 150#define fMP_ADAPTER_LOWER_POWER 0x00200000 151 152#define fMP_ADAPTER_NON_RECOVER_ERROR 0x00800000 153#define fMP_ADAPTER_HARDWARE_ERROR 0x04000000 154 155#define fMP_ADAPTER_FAIL_SEND_MASK 0x3ff00000 156 157/* Some offsets in PCI config space that are actually used. */ 158#define ET1310_PCI_MAC_ADDRESS 0xA4 159#define ET1310_PCI_EEPROM_STATUS 0xB2 160#define ET1310_PCI_ACK_NACK 0xC0 161#define ET1310_PCI_REPLAY 0xC2 162#define ET1310_PCI_L0L1LATENCY 0xCF 163 164/* PCI Product IDs */ 165#define ET131X_PCI_DEVICE_ID_GIG 0xED00 /* ET1310 1000 Base-T 8 */ 166#define ET131X_PCI_DEVICE_ID_FAST 0xED01 /* ET1310 100 Base-T */ 167 168/* Define order of magnitude converter */ 169#define NANO_IN_A_MICRO 1000 170 171#define PARM_RX_NUM_BUFS_DEF 4 172#define PARM_RX_TIME_INT_DEF 10 173#define PARM_RX_MEM_END_DEF 0x2bc 174#define PARM_TX_TIME_INT_DEF 40 175#define PARM_TX_NUM_BUFS_DEF 4 176#define PARM_DMA_CACHE_DEF 0 177 178/* RX defines */ 179#define USE_FBR0 1 180#define FBR_CHUNKS 32 181#define MAX_DESC_PER_RING_RX 1024 182 183/* number of RFDs - default and min */ 184#ifdef USE_FBR0 185#define RFD_LOW_WATER_MARK 40 186#define NIC_DEFAULT_NUM_RFD 1024 187#define NUM_FBRS 2 188#else 189#define RFD_LOW_WATER_MARK 20 190#define NIC_DEFAULT_NUM_RFD 256 191#define NUM_FBRS 1 192#endif 193 194#define NIC_MIN_NUM_RFD 64 195#define NUM_PACKETS_HANDLED 256 196 197#define ALCATEL_MULTICAST_PKT 0x01000000 198#define ALCATEL_BROADCAST_PKT 0x02000000 199 200/* typedefs for Free Buffer Descriptors */ 201struct fbr_desc { 202 u32 addr_lo; 203 u32 addr_hi; 204 u32 word2; /* Bits 10-31 reserved, 0-9 descriptor */ 205}; 206 207/* Packet Status Ring Descriptors 208 * 209 * Word 0: 210 * 211 * top 16 bits are from the Alcatel Status Word as enumerated in 212 * PE-MCXMAC Data Sheet IPD DS54 0210-1 (also IPD-DS80 0205-2) 213 * 214 * 0: hp hash pass 215 * 1: ipa IP checksum assist 216 * 2: ipp IP checksum pass 217 * 3: tcpa TCP checksum assist 218 * 4: tcpp TCP checksum pass 219 * 5: wol WOL Event 220 * 6: rxmac_error RXMAC Error Indicator 221 * 7: drop Drop packet 222 * 8: ft Frame Truncated 223 * 9: jp Jumbo Packet 224 * 10: vp VLAN Packet 225 * 11-15: unused 226 * 16: asw_prev_pkt_dropped e.g. IFG too small on previous 227 * 17: asw_RX_DV_event short receive event detected 228 * 18: asw_false_carrier_event bad carrier since last good packet 229 * 19: asw_code_err one or more nibbles signalled as errors 230 * 20: asw_CRC_err CRC error 231 * 21: asw_len_chk_err frame length field incorrect 232 * 22: asw_too_long frame length > 1518 bytes 233 * 23: asw_OK valid CRC + no code error 234 * 24: asw_multicast has a multicast address 235 * 25: asw_broadcast has a broadcast address 236 * 26: asw_dribble_nibble spurious bits after EOP 237 * 27: asw_control_frame is a control frame 238 * 28: asw_pause_frame is a pause frame 239 * 29: asw_unsupported_op unsupported OP code 240 * 30: asw_VLAN_tag VLAN tag detected 241 * 31: asw_long_evt Rx long event 242 * 243 * Word 1: 244 * 0-15: length length in bytes 245 * 16-25: bi Buffer Index 246 * 26-27: ri Ring Index 247 * 28-31: reserved 248 */ 249 250struct pkt_stat_desc { 251 u32 word0; 252 u32 word1; 253}; 254 255/* Typedefs for the RX DMA status word */ 256 257/* 258 * rx status word 0 holds part of the status bits of the Rx DMA engine 259 * that get copied out to memory by the ET-1310. Word 0 is a 32 bit word 260 * which contains the Free Buffer ring 0 and 1 available offset. 261 * 262 * bit 0-9 FBR1 offset 263 * bit 10 Wrap flag for FBR1 264 * bit 16-25 FBR0 offset 265 * bit 26 Wrap flag for FBR0 266 */ 267 268/* 269 * RXSTAT_WORD1_t structure holds part of the status bits of the Rx DMA engine 270 * that get copied out to memory by the ET-1310. Word 3 is a 32 bit word 271 * which contains the Packet Status Ring available offset. 272 * 273 * bit 0-15 reserved 274 * bit 16-27 PSRoffset 275 * bit 28 PSRwrap 276 * bit 29-31 unused 277 */ 278 279/* 280 * struct rx_status_block is a structure representing the status of the Rx 281 * DMA engine it sits in free memory, and is pointed to by 0x101c / 0x1020 282 */ 283struct rx_status_block { 284 u32 word0; 285 u32 word1; 286}; 287 288/* 289 * Structure for look-up table holding free buffer ring pointers, addresses 290 * and state. 291 */ 292struct fbr_lookup { 293 void *virt[MAX_DESC_PER_RING_RX]; 294 void *buffer1[MAX_DESC_PER_RING_RX]; 295 void *buffer2[MAX_DESC_PER_RING_RX]; 296 u32 bus_high[MAX_DESC_PER_RING_RX]; 297 u32 bus_low[MAX_DESC_PER_RING_RX]; 298 void *ring_virtaddr; 299 dma_addr_t ring_physaddr; 300 void *mem_virtaddrs[MAX_DESC_PER_RING_RX / FBR_CHUNKS]; 301 dma_addr_t mem_physaddrs[MAX_DESC_PER_RING_RX / FBR_CHUNKS]; 302 u64 real_physaddr; 303 u64 offset; 304 u32 local_full; 305 u32 num_entries; 306 u32 buffsize; 307}; 308 309/* 310 * struct rx_ring is the sructure representing the adaptor's local 311 * reference(s) to the rings 312 * 313 ****************************************************************************** 314 * IMPORTANT NOTE :- fbr_lookup *fbr[NUM_FBRS] uses index 0 to refer to FBR1 315 * and index 1 to refer to FRB0 316 ****************************************************************************** 317 */ 318struct rx_ring { 319 struct fbr_lookup *fbr[NUM_FBRS]; 320 void *ps_ring_virtaddr; 321 dma_addr_t ps_ring_physaddr; 322 u32 local_psr_full; 323 u32 psr_num_entries; 324 325 struct rx_status_block *rx_status_block; 326 dma_addr_t rx_status_bus; 327 328 /* RECV */ 329 struct list_head recv_list; 330 u32 num_ready_recv; 331 332 u32 num_rfd; 333 334 bool unfinished_receives; 335 336 /* lookaside lists */ 337 struct kmem_cache *recv_lookaside; 338}; 339 340/* TX defines */ 341/* 342 * word 2 of the control bits in the Tx Descriptor ring for the ET-1310 343 * 344 * 0-15: length of packet 345 * 16-27: VLAN tag 346 * 28: VLAN CFI 347 * 29-31: VLAN priority 348 * 349 * word 3 of the control bits in the Tx Descriptor ring for the ET-1310 350 * 351 * 0: last packet in the sequence 352 * 1: first packet in the sequence 353 * 2: interrupt the processor when this pkt sent 354 * 3: Control word - no packet data 355 * 4: Issue half-duplex backpressure : XON/XOFF 356 * 5: send pause frame 357 * 6: Tx frame has error 358 * 7: append CRC 359 * 8: MAC override 360 * 9: pad packet 361 * 10: Packet is a Huge packet 362 * 11: append VLAN tag 363 * 12: IP checksum assist 364 * 13: TCP checksum assist 365 * 14: UDP checksum assist 366 */ 367 368/* struct tx_desc represents each descriptor on the ring */ 369struct tx_desc { 370 u32 addr_hi; 371 u32 addr_lo; 372 u32 len_vlan; /* control words how to xmit the */ 373 u32 flags; /* data (detailed above) */ 374}; 375 376/* 377 * The status of the Tx DMA engine it sits in free memory, and is pointed to 378 * by 0x101c / 0x1020. This is a DMA10 type 379 */ 380 381/* TCB (Transmit Control Block: Host Side) */ 382struct tcb { 383 struct tcb *next; /* Next entry in ring */ 384 u32 flags; /* Our flags for the packet */ 385 u32 count; /* Used to spot stuck/lost packets */ 386 u32 stale; /* Used to spot stuck/lost packets */ 387 struct sk_buff *skb; /* Network skb we are tied to */ 388 u32 index; /* Ring indexes */ 389 u32 index_start; 390}; 391 392/* Structure representing our local reference(s) to the ring */ 393struct tx_ring { 394 /* TCB (Transmit Control Block) memory and lists */ 395 struct tcb *tcb_ring; 396 397 /* List of TCBs that are ready to be used */ 398 struct tcb *tcb_qhead; 399 struct tcb *tcb_qtail; 400 401 /* list of TCBs that are currently being sent. NOTE that access to all 402 * three of these (including used) are controlled via the 403 * TCBSendQLock. This lock should be secured prior to incementing / 404 * decrementing used, or any queue manipulation on send_head / 405 * tail 406 */ 407 struct tcb *send_head; 408 struct tcb *send_tail; 409 int used; 410 411 /* The actual descriptor ring */ 412 struct tx_desc *tx_desc_ring; 413 dma_addr_t tx_desc_ring_pa; 414 415 /* send_idx indicates where we last wrote to in the descriptor ring. */ 416 u32 send_idx; 417 418 /* The location of the write-back status block */ 419 u32 *tx_status; 420 dma_addr_t tx_status_pa; 421 422 /* Packets since the last IRQ: used for interrupt coalescing */ 423 int since_irq; 424}; 425 426/* 427 * Do not change these values: if changed, then change also in respective 428 * TXdma and Rxdma engines 429 */ 430#define NUM_DESC_PER_RING_TX 512 /* TX Do not change these values */ 431#define NUM_TCB 64 432 433/* 434 * These values are all superseded by registry entries to facilitate tuning. 435 * Once the desired performance has been achieved, the optimal registry values 436 * should be re-populated to these #defines: 437 */ 438#define TX_ERROR_PERIOD 1000 439 440#define LO_MARK_PERCENT_FOR_PSR 15 441#define LO_MARK_PERCENT_FOR_RX 15 442 443/* RFD (Receive Frame Descriptor) */ 444struct rfd { 445 struct list_head list_node; 446 struct sk_buff *skb; 447 u32 len; /* total size of receive frame */ 448 u16 bufferindex; 449 u8 ringindex; 450}; 451 452/* Flow Control */ 453#define FLOW_BOTH 0 454#define FLOW_TXONLY 1 455#define FLOW_RXONLY 2 456#define FLOW_NONE 3 457 458/* Struct to define some device statistics */ 459struct ce_stats { 460 /* MIB II variables 461 * 462 * NOTE: atomic_t types are only guaranteed to store 24-bits; if we 463 * MUST have 32, then we'll need another way to perform atomic 464 * operations 465 */ 466 u32 unicast_pkts_rcvd; 467 atomic_t unicast_pkts_xmtd; 468 u32 multicast_pkts_rcvd; 469 atomic_t multicast_pkts_xmtd; 470 u32 broadcast_pkts_rcvd; 471 atomic_t broadcast_pkts_xmtd; 472 u32 rcvd_pkts_dropped; 473 474 /* Tx Statistics. */ 475 u32 tx_underflows; 476 477 u32 tx_collisions; 478 u32 tx_excessive_collisions; 479 u32 tx_first_collisions; 480 u32 tx_late_collisions; 481 u32 tx_max_pkt_errs; 482 u32 tx_deferred; 483 484 /* Rx Statistics. */ 485 u32 rx_overflows; 486 487 u32 rx_length_errs; 488 u32 rx_align_errs; 489 u32 rx_crc_errs; 490 u32 rx_code_violations; 491 u32 rx_other_errs; 492 493 u32 synchronous_iterations; 494 u32 interrupt_status; 495}; 496 497/* The private adapter structure */ 498struct et131x_adapter { 499 struct net_device *netdev; 500 struct pci_dev *pdev; 501 struct mii_bus *mii_bus; 502 struct phy_device *phydev; 503 struct work_struct task; 504 505 /* Flags that indicate current state of the adapter */ 506 u32 flags; 507 508 /* local link state, to determine if a state change has occurred */ 509 int link; 510 511 /* Configuration */ 512 u8 rom_addr[ETH_ALEN]; 513 u8 addr[ETH_ALEN]; 514 bool has_eeprom; 515 u8 eeprom_data[2]; 516 517 /* Spinlocks */ 518 spinlock_t lock; 519 520 spinlock_t tcb_send_qlock; 521 spinlock_t tcb_ready_qlock; 522 spinlock_t send_hw_lock; 523 524 spinlock_t rcv_lock; 525 spinlock_t rcv_pend_lock; 526 spinlock_t fbr_lock; 527 528 spinlock_t phy_lock; 529 530 /* Packet Filter and look ahead size */ 531 u32 packet_filter; 532 533 /* multicast list */ 534 u32 multicast_addr_count; 535 u8 multicast_list[NIC_MAX_MCAST_LIST][ETH_ALEN]; 536 537 /* Pointer to the device's PCI register space */ 538 struct address_map __iomem *regs; 539 540 /* Registry parameters */ 541 u8 wanted_flow; /* Flow we want for 802.3x flow control */ 542 u32 registry_jumbo_packet; /* Max supported ethernet packet size */ 543 544 /* Derived from the registry: */ 545 u8 flowcontrol; /* flow control validated by the far-end */ 546 547 /* Minimize init-time */ 548 struct timer_list error_timer; 549 550 /* variable putting the phy into coma mode when boot up with no cable 551 * plugged in after 5 seconds 552 */ 553 u8 boot_coma; 554 555 /* Next two used to save power information at power down. This 556 * information will be used during power up to set up parts of Power 557 * Management in JAGCore 558 */ 559 u16 pdown_speed; 560 u8 pdown_duplex; 561 562 /* Tx Memory Variables */ 563 struct tx_ring tx_ring; 564 565 /* Rx Memory Variables */ 566 struct rx_ring rx_ring; 567 568 /* Stats */ 569 struct ce_stats stats; 570 571 struct net_device_stats net_stats; 572}; 573 574static int eeprom_wait_ready(struct pci_dev *pdev, u32 *status) 575{ 576 u32 reg; 577 int i; 578 579 /* 580 * 1. Check LBCIF Status Register for bits 6 & 3:2 all equal to 0 and 581 * bits 7,1:0 both equal to 1, at least once after reset. 582 * Subsequent operations need only to check that bits 1:0 are equal 583 * to 1 prior to starting a single byte read/write 584 */ 585 586 for (i = 0; i < MAX_NUM_REGISTER_POLLS; i++) { 587 /* Read registers grouped in DWORD1 */ 588 if (pci_read_config_dword(pdev, LBCIF_DWORD1_GROUP, &reg)) 589 return -EIO; 590 591 /* I2C idle and Phy Queue Avail both true */ 592 if ((reg & 0x3000) == 0x3000) { 593 if (status) 594 *status = reg; 595 return reg & 0xFF; 596 } 597 } 598 return -ETIMEDOUT; 599} 600 601 602/** 603 * eeprom_write - Write a byte to the ET1310's EEPROM 604 * @adapter: pointer to our private adapter structure 605 * @addr: the address to write 606 * @data: the value to write 607 * 608 * Returns 1 for a successful write. 609 */ 610static int eeprom_write(struct et131x_adapter *adapter, u32 addr, u8 data) 611{ 612 struct pci_dev *pdev = adapter->pdev; 613 int index = 0; 614 int retries; 615 int err = 0; 616 int i2c_wack = 0; 617 int writeok = 0; 618 u32 status; 619 u32 val = 0; 620 621 /* 622 * For an EEPROM, an I2C single byte write is defined as a START 623 * condition followed by the device address, EEPROM address, one byte 624 * of data and a STOP condition. The STOP condition will trigger the 625 * EEPROM's internally timed write cycle to the nonvolatile memory. 626 * All inputs are disabled during this write cycle and the EEPROM will 627 * not respond to any access until the internal write is complete. 628 */ 629 630 err = eeprom_wait_ready(pdev, NULL); 631 if (err) 632 return err; 633 634 /* 635 * 2. Write to the LBCIF Control Register: bit 7=1, bit 6=1, bit 3=0, 636 * and bits 1:0 both =0. Bit 5 should be set according to the 637 * type of EEPROM being accessed (1=two byte addressing, 0=one 638 * byte addressing). 639 */ 640 if (pci_write_config_byte(pdev, LBCIF_CONTROL_REGISTER, 641 LBCIF_CONTROL_LBCIF_ENABLE | LBCIF_CONTROL_I2C_WRITE)) 642 return -EIO; 643 644 i2c_wack = 1; 645 646 /* Prepare EEPROM address for Step 3 */ 647 648 for (retries = 0; retries < MAX_NUM_WRITE_RETRIES; retries++) { 649 /* Write the address to the LBCIF Address Register */ 650 if (pci_write_config_dword(pdev, LBCIF_ADDRESS_REGISTER, addr)) 651 break; 652 /* 653 * Write the data to the LBCIF Data Register (the I2C write 654 * will begin). 655 */ 656 if (pci_write_config_byte(pdev, LBCIF_DATA_REGISTER, data)) 657 break; 658 /* 659 * Monitor bit 1:0 of the LBCIF Status Register. When bits 660 * 1:0 are both equal to 1, the I2C write has completed and the 661 * internal write cycle of the EEPROM is about to start. 662 * (bits 1:0 = 01 is a legal state while waiting from both 663 * equal to 1, but bits 1:0 = 10 is invalid and implies that 664 * something is broken). 665 */ 666 err = eeprom_wait_ready(pdev, &status); 667 if (err < 0) 668 return 0; 669 670 /* 671 * Check bit 3 of the LBCIF Status Register. If equal to 1, 672 * an error has occurred.Don't break here if we are revision 673 * 1, this is so we do a blind write for load bug. 674 */ 675 if ((status & LBCIF_STATUS_GENERAL_ERROR) 676 && adapter->pdev->revision == 0) 677 break; 678 679 /* 680 * Check bit 2 of the LBCIF Status Register. If equal to 1 an 681 * ACK error has occurred on the address phase of the write. 682 * This could be due to an actual hardware failure or the 683 * EEPROM may still be in its internal write cycle from a 684 * previous write. This write operation was ignored and must be 685 *repeated later. 686 */ 687 if (status & LBCIF_STATUS_ACK_ERROR) { 688 /* 689 * This could be due to an actual hardware failure 690 * or the EEPROM may still be in its internal write 691 * cycle from a previous write. This write operation 692 * was ignored and must be repeated later. 693 */ 694 udelay(10); 695 continue; 696 } 697 698 writeok = 1; 699 break; 700 } 701 702 /* 703 * Set bit 6 of the LBCIF Control Register = 0. 704 */ 705 udelay(10); 706 707 while (i2c_wack) { 708 if (pci_write_config_byte(pdev, LBCIF_CONTROL_REGISTER, 709 LBCIF_CONTROL_LBCIF_ENABLE)) 710 writeok = 0; 711 712 /* Do read until internal ACK_ERROR goes away meaning write 713 * completed 714 */ 715 do { 716 pci_write_config_dword(pdev, 717 LBCIF_ADDRESS_REGISTER, 718 addr); 719 do { 720 pci_read_config_dword(pdev, 721 LBCIF_DATA_REGISTER, &val); 722 } while ((val & 0x00010000) == 0); 723 } while (val & 0x00040000); 724 725 if ((val & 0xFF00) != 0xC000 || index == 10000) 726 break; 727 index++; 728 } 729 return writeok ? 0 : -EIO; 730} 731 732/** 733 * eeprom_read - Read a byte from the ET1310's EEPROM 734 * @adapter: pointer to our private adapter structure 735 * @addr: the address from which to read 736 * @pdata: a pointer to a byte in which to store the value of the read 737 * @eeprom_id: the ID of the EEPROM 738 * @addrmode: how the EEPROM is to be accessed 739 * 740 * Returns 1 for a successful read 741 */ 742static int eeprom_read(struct et131x_adapter *adapter, u32 addr, u8 *pdata) 743{ 744 struct pci_dev *pdev = adapter->pdev; 745 int err; 746 u32 status; 747 748 /* 749 * A single byte read is similar to the single byte write, with the 750 * exception of the data flow: 751 */ 752 753 err = eeprom_wait_ready(pdev, NULL); 754 if (err) 755 return err; 756 /* 757 * Write to the LBCIF Control Register: bit 7=1, bit 6=0, bit 3=0, 758 * and bits 1:0 both =0. Bit 5 should be set according to the type 759 * of EEPROM being accessed (1=two byte addressing, 0=one byte 760 * addressing). 761 */ 762 if (pci_write_config_byte(pdev, LBCIF_CONTROL_REGISTER, 763 LBCIF_CONTROL_LBCIF_ENABLE)) 764 return -EIO; 765 /* 766 * Write the address to the LBCIF Address Register (I2C read will 767 * begin). 768 */ 769 if (pci_write_config_dword(pdev, LBCIF_ADDRESS_REGISTER, addr)) 770 return -EIO; 771 /* 772 * Monitor bit 0 of the LBCIF Status Register. When = 1, I2C read 773 * is complete. (if bit 1 =1 and bit 0 stays = 0, a hardware failure 774 * has occurred). 775 */ 776 err = eeprom_wait_ready(pdev, &status); 777 if (err < 0) 778 return err; 779 /* 780 * Regardless of error status, read data byte from LBCIF Data 781 * Register. 782 */ 783 *pdata = err; 784 /* 785 * Check bit 2 of the LBCIF Status Register. If = 1, 786 * then an error has occurred. 787 */ 788 return (status & LBCIF_STATUS_ACK_ERROR) ? -EIO : 0; 789} 790 791static int et131x_init_eeprom(struct et131x_adapter *adapter) 792{ 793 struct pci_dev *pdev = adapter->pdev; 794 u8 eestatus; 795 796 /* We first need to check the EEPROM Status code located at offset 797 * 0xB2 of config space 798 */ 799 pci_read_config_byte(pdev, ET1310_PCI_EEPROM_STATUS, 800 &eestatus); 801 802 /* THIS IS A WORKAROUND: 803 * I need to call this function twice to get my card in a 804 * LG M1 Express Dual running. I tried also a msleep before this 805 * function, because I thought there could be some time condidions 806 * but it didn't work. Call the whole function twice also work. 807 */ 808 if (pci_read_config_byte(pdev, ET1310_PCI_EEPROM_STATUS, &eestatus)) { 809 dev_err(&pdev->dev, 810 "Could not read PCI config space for EEPROM Status\n"); 811 return -EIO; 812 } 813 814 /* Determine if the error(s) we care about are present. If they are 815 * present we need to fail. 816 */ 817 if (eestatus & 0x4C) { 818 int write_failed = 0; 819 if (pdev->revision == 0x01) { 820 int i; 821 static const u8 eedata[4] = { 0xFE, 0x13, 0x10, 0xFF }; 822 823 /* Re-write the first 4 bytes if we have an eeprom 824 * present and the revision id is 1, this fixes the 825 * corruption seen with 1310 B Silicon 826 */ 827 for (i = 0; i < 3; i++) 828 if (eeprom_write(adapter, i, eedata[i]) < 0) 829 write_failed = 1; 830 } 831 if (pdev->revision != 0x01 || write_failed) { 832 dev_err(&pdev->dev, 833 "Fatal EEPROM Status Error - 0x%04x\n", eestatus); 834 835 /* This error could mean that there was an error 836 * reading the eeprom or that the eeprom doesn't exist. 837 * We will treat each case the same and not try to 838 * gather additional information that normally would 839 * come from the eeprom, like MAC Address 840 */ 841 adapter->has_eeprom = 0; 842 return -EIO; 843 } 844 } 845 adapter->has_eeprom = 1; 846 847 /* Read the EEPROM for information regarding LED behavior. Refer to 848 * ET1310_phy.c, et131x_xcvr_init(), for its use. 849 */ 850 eeprom_read(adapter, 0x70, &adapter->eeprom_data[0]); 851 eeprom_read(adapter, 0x71, &adapter->eeprom_data[1]); 852 853 if (adapter->eeprom_data[0] != 0xcd) 854 /* Disable all optional features */ 855 adapter->eeprom_data[1] = 0x00; 856 857 return 0; 858} 859 860/** 861 * et131x_rx_dma_enable - re-start of Rx_DMA on the ET1310. 862 * @adapter: pointer to our adapter structure 863 */ 864static void et131x_rx_dma_enable(struct et131x_adapter *adapter) 865{ 866 /* Setup the receive dma configuration register for normal operation */ 867 u32 csr = 0x2000; /* FBR1 enable */ 868 869 if (adapter->rx_ring.fbr[0]->buffsize == 4096) 870 csr |= 0x0800; 871 else if (adapter->rx_ring.fbr[0]->buffsize == 8192) 872 csr |= 0x1000; 873 else if (adapter->rx_ring.fbr[0]->buffsize == 16384) 874 csr |= 0x1800; 875#ifdef USE_FBR0 876 csr |= 0x0400; /* FBR0 enable */ 877 if (adapter->rx_ring.fbr[1]->buffsize == 256) 878 csr |= 0x0100; 879 else if (adapter->rx_ring.fbr[1]->buffsize == 512) 880 csr |= 0x0200; 881 else if (adapter->rx_ring.fbr[1]->buffsize == 1024) 882 csr |= 0x0300; 883#endif 884 writel(csr, &adapter->regs->rxdma.csr); 885 886 csr = readl(&adapter->regs->rxdma.csr); 887 if ((csr & 0x00020000) != 0) { 888 udelay(5); 889 csr = readl(&adapter->regs->rxdma.csr); 890 if ((csr & 0x00020000) != 0) { 891 dev_err(&adapter->pdev->dev, 892 "RX Dma failed to exit halt state. CSR 0x%08x\n", 893 csr); 894 } 895 } 896} 897 898/** 899 * et131x_rx_dma_disable - Stop of Rx_DMA on the ET1310 900 * @adapter: pointer to our adapter structure 901 */ 902static void et131x_rx_dma_disable(struct et131x_adapter *adapter) 903{ 904 u32 csr; 905 /* Setup the receive dma configuration register */ 906 writel(0x00002001, &adapter->regs->rxdma.csr); 907 csr = readl(&adapter->regs->rxdma.csr); 908 if ((csr & 0x00020000) == 0) { /* Check halt status (bit 17) */ 909 udelay(5); 910 csr = readl(&adapter->regs->rxdma.csr); 911 if ((csr & 0x00020000) == 0) 912 dev_err(&adapter->pdev->dev, 913 "RX Dma failed to enter halt state. CSR 0x%08x\n", 914 csr); 915 } 916} 917 918/** 919 * et131x_tx_dma_enable - re-start of Tx_DMA on the ET1310. 920 * @adapter: pointer to our adapter structure 921 * 922 * Mainly used after a return to the D0 (full-power) state from a lower state. 923 */ 924static void et131x_tx_dma_enable(struct et131x_adapter *adapter) 925{ 926 /* Setup the transmit dma configuration register for normal 927 * operation 928 */ 929 writel(ET_TXDMA_SNGL_EPKT|(PARM_DMA_CACHE_DEF << ET_TXDMA_CACHE_SHIFT), 930 &adapter->regs->txdma.csr); 931} 932 933static inline void add_10bit(u32 *v, int n) 934{ 935 *v = INDEX10(*v + n) | (*v & ET_DMA10_WRAP); 936} 937 938static inline void add_12bit(u32 *v, int n) 939{ 940 *v = INDEX12(*v + n) | (*v & ET_DMA12_WRAP); 941} 942 943/** 944 * et1310_config_mac_regs1 - Initialize the first part of MAC regs 945 * @adapter: pointer to our adapter structure 946 */ 947static void et1310_config_mac_regs1(struct et131x_adapter *adapter) 948{ 949 struct mac_regs __iomem *macregs = &adapter->regs->mac; 950 u32 station1; 951 u32 station2; 952 u32 ipg; 953 954 /* First we need to reset everything. Write to MAC configuration 955 * register 1 to perform reset. 956 */ 957 writel(0xC00F0000, &macregs->cfg1); 958 959 /* Next lets configure the MAC Inter-packet gap register */ 960 ipg = 0x38005860; /* IPG1 0x38 IPG2 0x58 B2B 0x60 */ 961 ipg |= 0x50 << 8; /* ifg enforce 0x50 */ 962 writel(ipg, &macregs->ipg); 963 964 /* Next lets configure the MAC Half Duplex register */ 965 /* BEB trunc 0xA, Ex Defer, Rexmit 0xF Coll 0x37 */ 966 writel(0x00A1F037, &macregs->hfdp); 967 968 /* Next lets configure the MAC Interface Control register */ 969 writel(0, &macregs->if_ctrl); 970 971 /* Let's move on to setting up the mii management configuration */ 972 writel(0x07, &macregs->mii_mgmt_cfg); /* Clock reset 0x7 */ 973 974 /* Next lets configure the MAC Station Address register. These 975 * values are read from the EEPROM during initialization and stored 976 * in the adapter structure. We write what is stored in the adapter 977 * structure to the MAC Station Address registers high and low. This 978 * station address is used for generating and checking pause control 979 * packets. 980 */ 981 station2 = (adapter->addr[1] << ET_MAC_STATION_ADDR2_OC2_SHIFT) | 982 (adapter->addr[0] << ET_MAC_STATION_ADDR2_OC1_SHIFT); 983 station1 = (adapter->addr[5] << ET_MAC_STATION_ADDR1_OC6_SHIFT) | 984 (adapter->addr[4] << ET_MAC_STATION_ADDR1_OC5_SHIFT) | 985 (adapter->addr[3] << ET_MAC_STATION_ADDR1_OC4_SHIFT) | 986 adapter->addr[2]; 987 writel(station1, &macregs->station_addr_1); 988 writel(station2, &macregs->station_addr_2); 989 990 /* Max ethernet packet in bytes that will be passed by the mac without 991 * being truncated. Allow the MAC to pass 4 more than our max packet 992 * size. This is 4 for the Ethernet CRC. 993 * 994 * Packets larger than (registry_jumbo_packet) that do not contain a 995 * VLAN ID will be dropped by the Rx function. 996 */ 997 writel(adapter->registry_jumbo_packet + 4, &macregs->max_fm_len); 998 999 /* clear out MAC config reset */ 1000 writel(0, &macregs->cfg1); 1001} 1002 1003/** 1004 * et1310_config_mac_regs2 - Initialize the second part of MAC regs 1005 * @adapter: pointer to our adapter structure 1006 */ 1007static void et1310_config_mac_regs2(struct et131x_adapter *adapter) 1008{ 1009 int32_t delay = 0; 1010 struct mac_regs __iomem *mac = &adapter->regs->mac; 1011 struct phy_device *phydev = adapter->phydev; 1012 u32 cfg1; 1013 u32 cfg2; 1014 u32 ifctrl; 1015 u32 ctl; 1016 1017 ctl = readl(&adapter->regs->txmac.ctl); 1018 cfg1 = readl(&mac->cfg1); 1019 cfg2 = readl(&mac->cfg2); 1020 ifctrl = readl(&mac->if_ctrl); 1021 1022 /* Set up the if mode bits */ 1023 cfg2 &= ~0x300; 1024 if (phydev && phydev->speed == SPEED_1000) { 1025 cfg2 |= 0x200; 1026 /* Phy mode bit */ 1027 ifctrl &= ~(1 << 24); 1028 } else { 1029 cfg2 |= 0x100; 1030 ifctrl |= (1 << 24); 1031 } 1032 1033 /* We need to enable Rx/Tx */ 1034 cfg1 |= CFG1_RX_ENABLE | CFG1_TX_ENABLE | CFG1_TX_FLOW; 1035 /* Initialize loop back to off */ 1036 cfg1 &= ~(CFG1_LOOPBACK | CFG1_RX_FLOW); 1037 if (adapter->flowcontrol == FLOW_RXONLY || 1038 adapter->flowcontrol == FLOW_BOTH) 1039 cfg1 |= CFG1_RX_FLOW; 1040 writel(cfg1, &mac->cfg1); 1041 1042 /* Now we need to initialize the MAC Configuration 2 register */ 1043 /* preamble 7, check length, huge frame off, pad crc, crc enable 1044 full duplex off */ 1045 cfg2 |= 0x7016; 1046 cfg2 &= ~0x0021; 1047 1048 /* Turn on duplex if needed */ 1049 if (phydev && phydev->duplex == DUPLEX_FULL) 1050 cfg2 |= 0x01; 1051 1052 ifctrl &= ~(1 << 26); 1053 if (phydev && phydev->duplex == DUPLEX_HALF) 1054 ifctrl |= (1<<26); /* Enable ghd */ 1055 1056 writel(ifctrl, &mac->if_ctrl); 1057 writel(cfg2, &mac->cfg2); 1058 1059 do { 1060 udelay(10); 1061 delay++; 1062 cfg1 = readl(&mac->cfg1); 1063 } while ((cfg1 & CFG1_WAIT) != CFG1_WAIT && delay < 100); 1064 1065 if (delay == 100) { 1066 dev_warn(&adapter->pdev->dev, 1067 "Syncd bits did not respond correctly cfg1 word 0x%08x\n", 1068 cfg1); 1069 } 1070 1071 /* Enable txmac */ 1072 ctl |= 0x09; /* TX mac enable, FC disable */ 1073 writel(ctl, &adapter->regs->txmac.ctl); 1074 1075 /* Ready to start the RXDMA/TXDMA engine */ 1076 if (adapter->flags & fMP_ADAPTER_LOWER_POWER) { 1077 et131x_rx_dma_enable(adapter); 1078 et131x_tx_dma_enable(adapter); 1079 } 1080} 1081 1082/** 1083 * et1310_in_phy_coma - check if the device is in phy coma 1084 * @adapter: pointer to our adapter structure 1085 * 1086 * Returns 0 if the device is not in phy coma, 1 if it is in phy coma 1087 */ 1088static int et1310_in_phy_coma(struct et131x_adapter *adapter) 1089{ 1090 u32 pmcsr; 1091 1092 pmcsr = readl(&adapter->regs->global.pm_csr); 1093 1094 return ET_PM_PHY_SW_COMA & pmcsr ? 1 : 0; 1095} 1096 1097static void et1310_setup_device_for_multicast(struct et131x_adapter *adapter) 1098{ 1099 struct rxmac_regs __iomem *rxmac = &adapter->regs->rxmac; 1100 u32 hash1 = 0; 1101 u32 hash2 = 0; 1102 u32 hash3 = 0; 1103 u32 hash4 = 0; 1104 u32 pm_csr; 1105 1106 /* If ET131X_PACKET_TYPE_MULTICAST is specified, then we provision 1107 * the multi-cast LIST. If it is NOT specified, (and "ALL" is not 1108 * specified) then we should pass NO multi-cast addresses to the 1109 * driver. 1110 */ 1111 if (adapter->packet_filter & ET131X_PACKET_TYPE_MULTICAST) { 1112 int i; 1113 1114 /* Loop through our multicast array and set up the device */ 1115 for (i = 0; i < adapter->multicast_addr_count; i++) { 1116 u32 result; 1117 1118 result = ether_crc(6, adapter->multicast_list[i]); 1119 1120 result = (result & 0x3F800000) >> 23; 1121 1122 if (result < 32) { 1123 hash1 |= (1 << result); 1124 } else if ((31 < result) && (result < 64)) { 1125 result -= 32; 1126 hash2 |= (1 << result); 1127 } else if ((63 < result) && (result < 96)) { 1128 result -= 64; 1129 hash3 |= (1 << result); 1130 } else { 1131 result -= 96; 1132 hash4 |= (1 << result); 1133 } 1134 } 1135 } 1136 1137 /* Write out the new hash to the device */ 1138 pm_csr = readl(&adapter->regs->global.pm_csr); 1139 if (!et1310_in_phy_coma(adapter)) { 1140 writel(hash1, &rxmac->multi_hash1); 1141 writel(hash2, &rxmac->multi_hash2); 1142 writel(hash3, &rxmac->multi_hash3); 1143 writel(hash4, &rxmac->multi_hash4); 1144 } 1145} 1146 1147static void et1310_setup_device_for_unicast(struct et131x_adapter *adapter) 1148{ 1149 struct rxmac_regs __iomem *rxmac = &adapter->regs->rxmac; 1150 u32 uni_pf1; 1151 u32 uni_pf2; 1152 u32 uni_pf3; 1153 u32 pm_csr; 1154 1155 /* Set up unicast packet filter reg 3 to be the first two octets of 1156 * the MAC address for both address 1157 * 1158 * Set up unicast packet filter reg 2 to be the octets 2 - 5 of the 1159 * MAC address for second address 1160 * 1161 * Set up unicast packet filter reg 3 to be the octets 2 - 5 of the 1162 * MAC address for first address 1163 */ 1164 uni_pf3 = (adapter->addr[0] << ET_UNI_PF_ADDR2_1_SHIFT) | 1165 (adapter->addr[1] << ET_UNI_PF_ADDR2_2_SHIFT) | 1166 (adapter->addr[0] << ET_UNI_PF_ADDR1_1_SHIFT) | 1167 adapter->addr[1]; 1168 1169 uni_pf2 = (adapter->addr[2] << ET_UNI_PF_ADDR2_3_SHIFT) | 1170 (adapter->addr[3] << ET_UNI_PF_ADDR2_4_SHIFT) | 1171 (adapter->addr[4] << ET_UNI_PF_ADDR2_5_SHIFT) | 1172 adapter->addr[5]; 1173 1174 uni_pf1 = (adapter->addr[2] << ET_UNI_PF_ADDR1_3_SHIFT) | 1175 (adapter->addr[3] << ET_UNI_PF_ADDR1_4_SHIFT) | 1176 (adapter->addr[4] << ET_UNI_PF_ADDR1_5_SHIFT) | 1177 adapter->addr[5]; 1178 1179 pm_csr = readl(&adapter->regs->global.pm_csr); 1180 if (!et1310_in_phy_coma(adapter)) { 1181 writel(uni_pf1, &rxmac->uni_pf_addr1); 1182 writel(uni_pf2, &rxmac->uni_pf_addr2); 1183 writel(uni_pf3, &rxmac->uni_pf_addr3); 1184 } 1185} 1186 1187static void et1310_config_rxmac_regs(struct et131x_adapter *adapter) 1188{ 1189 struct rxmac_regs __iomem *rxmac = &adapter->regs->rxmac; 1190 struct phy_device *phydev = adapter->phydev; 1191 u32 sa_lo; 1192 u32 sa_hi = 0; 1193 u32 pf_ctrl = 0; 1194 1195 /* Disable the MAC while it is being configured (also disable WOL) */ 1196 writel(0x8, &rxmac->ctrl); 1197 1198 /* Initialize WOL to disabled. */ 1199 writel(0, &rxmac->crc0); 1200 writel(0, &rxmac->crc12); 1201 writel(0, &rxmac->crc34); 1202 1203 /* We need to set the WOL mask0 - mask4 next. We initialize it to 1204 * its default Values of 0x00000000 because there are not WOL masks 1205 * as of this time. 1206 */ 1207 writel(0, &rxmac->mask0_word0); 1208 writel(0, &rxmac->mask0_word1); 1209 writel(0, &rxmac->mask0_word2); 1210 writel(0, &rxmac->mask0_word3); 1211 1212 writel(0, &rxmac->mask1_word0); 1213 writel(0, &rxmac->mask1_word1); 1214 writel(0, &rxmac->mask1_word2); 1215 writel(0, &rxmac->mask1_word3); 1216 1217 writel(0, &rxmac->mask2_word0); 1218 writel(0, &rxmac->mask2_word1); 1219 writel(0, &rxmac->mask2_word2); 1220 writel(0, &rxmac->mask2_word3); 1221 1222 writel(0, &rxmac->mask3_word0); 1223 writel(0, &rxmac->mask3_word1); 1224 writel(0, &rxmac->mask3_word2); 1225 writel(0, &rxmac->mask3_word3); 1226 1227 writel(0, &rxmac->mask4_word0); 1228 writel(0, &rxmac->mask4_word1); 1229 writel(0, &rxmac->mask4_word2); 1230 writel(0, &rxmac->mask4_word3); 1231 1232 /* Lets setup the WOL Source Address */ 1233 sa_lo = (adapter->addr[2] << ET_WOL_LO_SA3_SHIFT) | 1234 (adapter->addr[3] << ET_WOL_LO_SA4_SHIFT) | 1235 (adapter->addr[4] << ET_WOL_LO_SA5_SHIFT) | 1236 adapter->addr[5]; 1237 writel(sa_lo, &rxmac->sa_lo); 1238 1239 sa_hi = (u32) (adapter->addr[0] << ET_WOL_HI_SA1_SHIFT) | 1240 adapter->addr[1]; 1241 writel(sa_hi, &rxmac->sa_hi); 1242 1243 /* Disable all Packet Filtering */ 1244 writel(0, &rxmac->pf_ctrl); 1245 1246 /* Let's initialize the Unicast Packet filtering address */ 1247 if (adapter->packet_filter & ET131X_PACKET_TYPE_DIRECTED) { 1248 et1310_setup_device_for_unicast(adapter); 1249 pf_ctrl |= 4; /* Unicast filter */ 1250 } else { 1251 writel(0, &rxmac->uni_pf_addr1); 1252 writel(0, &rxmac->uni_pf_addr2); 1253 writel(0, &rxmac->uni_pf_addr3); 1254 } 1255 1256 /* Let's initialize the Multicast hash */ 1257 if (!(adapter->packet_filter & ET131X_PACKET_TYPE_ALL_MULTICAST)) { 1258 pf_ctrl |= 2; /* Multicast filter */ 1259 et1310_setup_device_for_multicast(adapter); 1260 } 1261 1262 /* Runt packet filtering. Didn't work in version A silicon. */ 1263 pf_ctrl |= (NIC_MIN_PACKET_SIZE + 4) << 16; 1264 pf_ctrl |= 8; /* Fragment filter */ 1265 1266 if (adapter->registry_jumbo_packet > 8192) 1267 /* In order to transmit jumbo packets greater than 8k, the 1268 * FIFO between RxMAC and RxDMA needs to be reduced in size 1269 * to (16k - Jumbo packet size). In order to implement this, 1270 * we must use "cut through" mode in the RxMAC, which chops 1271 * packets down into segments which are (max_size * 16). In 1272 * this case we selected 256 bytes, since this is the size of 1273 * the PCI-Express TLP's that the 1310 uses. 1274 * 1275 * seg_en on, fc_en off, size 0x10 1276 */ 1277 writel(0x41, &rxmac->mcif_ctrl_max_seg); 1278 else 1279 writel(0, &rxmac->mcif_ctrl_max_seg); 1280 1281 /* Initialize the MCIF water marks */ 1282 writel(0, &rxmac->mcif_water_mark); 1283 1284 /* Initialize the MIF control */ 1285 writel(0, &rxmac->mif_ctrl); 1286 1287 /* Initialize the Space Available Register */ 1288 writel(0, &rxmac->space_avail); 1289 1290 /* Initialize the the mif_ctrl register 1291 * bit 3: Receive code error. One or more nibbles were signaled as 1292 * errors during the reception of the packet. Clear this 1293 * bit in Gigabit, set it in 100Mbit. This was derived 1294 * experimentally at UNH. 1295 * bit 4: Receive CRC error. The packet's CRC did not match the 1296 * internally generated CRC. 1297 * bit 5: Receive length check error. Indicates that frame length 1298 * field value in the packet does not match the actual data 1299 * byte length and is not a type field. 1300 * bit 16: Receive frame truncated. 1301 * bit 17: Drop packet enable 1302 */ 1303 if (phydev && phydev->speed == SPEED_100) 1304 writel(0x30038, &rxmac->mif_ctrl); 1305 else 1306 writel(0x30030, &rxmac->mif_ctrl); 1307 1308 /* Finally we initialize RxMac to be enabled & WOL disabled. Packet 1309 * filter is always enabled since it is where the runt packets are 1310 * supposed to be dropped. For version A silicon, runt packet 1311 * dropping doesn't work, so it is disabled in the pf_ctrl register, 1312 * but we still leave the packet filter on. 1313 */ 1314 writel(pf_ctrl, &rxmac->pf_ctrl); 1315 writel(0x9, &rxmac->ctrl); 1316} 1317 1318static void et1310_config_txmac_regs(struct et131x_adapter *adapter) 1319{ 1320 struct txmac_regs __iomem *txmac = &adapter->regs->txmac; 1321 1322 /* We need to update the Control Frame Parameters 1323 * cfpt - control frame pause timer set to 64 (0x40) 1324 * cfep - control frame extended pause timer set to 0x0 1325 */ 1326 if (adapter->flowcontrol == FLOW_NONE) 1327 writel(0, &txmac->cf_param); 1328 else 1329 writel(0x40, &txmac->cf_param); 1330} 1331 1332static void et1310_config_macstat_regs(struct et131x_adapter *adapter) 1333{ 1334 struct macstat_regs __iomem *macstat = 1335 &adapter->regs->macstat; 1336 1337 /* Next we need to initialize all the macstat registers to zero on 1338 * the device. 1339 */ 1340 writel(0, &macstat->txrx_0_64_byte_frames); 1341 writel(0, &macstat->txrx_65_127_byte_frames); 1342 writel(0, &macstat->txrx_128_255_byte_frames); 1343 writel(0, &macstat->txrx_256_511_byte_frames); 1344 writel(0, &macstat->txrx_512_1023_byte_frames); 1345 writel(0, &macstat->txrx_1024_1518_byte_frames); 1346 writel(0, &macstat->txrx_1519_1522_gvln_frames); 1347 1348 writel(0, &macstat->rx_bytes); 1349 writel(0, &macstat->rx_packets); 1350 writel(0, &macstat->rx_fcs_errs); 1351 writel(0, &macstat->rx_multicast_packets); 1352 writel(0, &macstat->rx_broadcast_packets); 1353 writel(0, &macstat->rx_control_frames); 1354 writel(0, &macstat->rx_pause_frames); 1355 writel(0, &macstat->rx_unknown_opcodes); 1356 writel(0, &macstat->rx_align_errs); 1357 writel(0, &macstat->rx_frame_len_errs); 1358 writel(0, &macstat->rx_code_errs); 1359 writel(0, &macstat->rx_carrier_sense_errs); 1360 writel(0, &macstat->rx_undersize_packets); 1361 writel(0, &macstat->rx_oversize_packets); 1362 writel(0, &macstat->rx_fragment_packets); 1363 writel(0, &macstat->rx_jabbers); 1364 writel(0, &macstat->rx_drops); 1365 1366 writel(0, &macstat->tx_bytes); 1367 writel(0, &macstat->tx_packets); 1368 writel(0, &macstat->tx_multicast_packets); 1369 writel(0, &macstat->tx_broadcast_packets); 1370 writel(0, &macstat->tx_pause_frames); 1371 writel(0, &macstat->tx_deferred); 1372 writel(0, &macstat->tx_excessive_deferred); 1373 writel(0, &macstat->tx_single_collisions); 1374 writel(0, &macstat->tx_multiple_collisions); 1375 writel(0, &macstat->tx_late_collisions); 1376 writel(0, &macstat->tx_excessive_collisions); 1377 writel(0, &macstat->tx_total_collisions); 1378 writel(0, &macstat->tx_pause_honored_frames); 1379 writel(0, &macstat->tx_drops); 1380 writel(0, &macstat->tx_jabbers); 1381 writel(0, &macstat->tx_fcs_errs); 1382 writel(0, &macstat->tx_control_frames); 1383 writel(0, &macstat->tx_oversize_frames); 1384 writel(0, &macstat->tx_undersize_frames); 1385 writel(0, &macstat->tx_fragments); 1386 writel(0, &macstat->carry_reg1); 1387 writel(0, &macstat->carry_reg2); 1388 1389 /* Unmask any counters that we want to track the overflow of. 1390 * Initially this will be all counters. It may become clear later 1391 * that we do not need to track all counters. 1392 */ 1393 writel(0xFFFFBE32, &macstat->carry_reg1_mask); 1394 writel(0xFFFE7E8B, &macstat->carry_reg2_mask); 1395} 1396 1397/** 1398 * et131x_phy_mii_read - Read from the PHY through the MII Interface on the MAC 1399 * @adapter: pointer to our private adapter structure 1400 * @addr: the address of the transceiver 1401 * @reg: the register to read 1402 * @value: pointer to a 16-bit value in which the value will be stored 1403 * 1404 * Returns 0 on success, errno on failure (as defined in errno.h) 1405 */ 1406static int et131x_phy_mii_read(struct et131x_adapter *adapter, u8 addr, 1407 u8 reg, u16 *value) 1408{ 1409 struct mac_regs __iomem *mac = &adapter->regs->mac; 1410 int status = 0; 1411 u32 delay = 0; 1412 u32 mii_addr; 1413 u32 mii_cmd; 1414 u32 mii_indicator; 1415 1416 /* Save a local copy of the registers we are dealing with so we can 1417 * set them back 1418 */ 1419 mii_addr = readl(&mac->mii_mgmt_addr); 1420 mii_cmd = readl(&mac->mii_mgmt_cmd); 1421 1422 /* Stop the current operation */ 1423 writel(0, &mac->mii_mgmt_cmd); 1424 1425 /* Set up the register we need to read from on the correct PHY */ 1426 writel(MII_ADDR(addr, reg), &mac->mii_mgmt_addr); 1427 1428 writel(0x1, &mac->mii_mgmt_cmd); 1429 1430 do { 1431 udelay(50); 1432 delay++; 1433 mii_indicator = readl(&mac->mii_mgmt_indicator); 1434 } while ((mii_indicator & MGMT_WAIT) && delay < 50); 1435 1436 /* If we hit the max delay, we could not read the register */ 1437 if (delay == 50) { 1438 dev_warn(&adapter->pdev->dev, 1439 "reg 0x%08x could not be read\n", reg); 1440 dev_warn(&adapter->pdev->dev, "status is 0x%08x\n", 1441 mii_indicator); 1442 1443 status = -EIO; 1444 } 1445 1446 /* If we hit here we were able to read the register and we need to 1447 * return the value to the caller */ 1448 *value = readl(&mac->mii_mgmt_stat) & 0xFFFF; 1449 1450 /* Stop the read operation */ 1451 writel(0, &mac->mii_mgmt_cmd); 1452 1453 /* set the registers we touched back to the state at which we entered 1454 * this function 1455 */ 1456 writel(mii_addr, &mac->mii_mgmt_addr); 1457 writel(mii_cmd, &mac->mii_mgmt_cmd); 1458 1459 return status; 1460} 1461 1462static int et131x_mii_read(struct et131x_adapter *adapter, u8 reg, u16 *value) 1463{ 1464 struct phy_device *phydev = adapter->phydev; 1465 1466 if (!phydev) 1467 return -EIO; 1468 1469 return et131x_phy_mii_read(adapter, phydev->addr, reg, value); 1470} 1471 1472/** 1473 * et131x_mii_write - Write to a PHY register through the MII interface of the MAC 1474 * @adapter: pointer to our private adapter structure 1475 * @reg: the register to read 1476 * @value: 16-bit value to write 1477 * 1478 * FIXME: one caller in netdev still 1479 * 1480 * Return 0 on success, errno on failure (as defined in errno.h) 1481 */ 1482static int et131x_mii_write(struct et131x_adapter *adapter, u8 reg, u16 value) 1483{ 1484 struct mac_regs __iomem *mac = &adapter->regs->mac; 1485 struct phy_device *phydev = adapter->phydev; 1486 int status = 0; 1487 u8 addr; 1488 u32 delay = 0; 1489 u32 mii_addr; 1490 u32 mii_cmd; 1491 u32 mii_indicator; 1492 1493 if (!phydev) 1494 return -EIO; 1495 1496 addr = phydev->addr; 1497 1498 /* Save a local copy of the registers we are dealing with so we can 1499 * set them back 1500 */ 1501 mii_addr = readl(&mac->mii_mgmt_addr); 1502 mii_cmd = readl(&mac->mii_mgmt_cmd); 1503 1504 /* Stop the current operation */ 1505 writel(0, &mac->mii_mgmt_cmd); 1506 1507 /* Set up the register we need to write to on the correct PHY */ 1508 writel(MII_ADDR(addr, reg), &mac->mii_mgmt_addr); 1509 1510 /* Add the value to write to the registers to the mac */ 1511 writel(value, &mac->mii_mgmt_ctrl); 1512 1513 do { 1514 udelay(50); 1515 delay++; 1516 mii_indicator = readl(&mac->mii_mgmt_indicator); 1517 } while ((mii_indicator & MGMT_BUSY) && delay < 100); 1518 1519 /* If we hit the max delay, we could not write the register */ 1520 if (delay == 100) { 1521 u16 tmp; 1522 1523 dev_warn(&adapter->pdev->dev, 1524 "reg 0x%08x could not be written", reg); 1525 dev_warn(&adapter->pdev->dev, "status is 0x%08x\n", 1526 mii_indicator); 1527 dev_warn(&adapter->pdev->dev, "command is 0x%08x\n", 1528 readl(&mac->mii_mgmt_cmd)); 1529 1530 et131x_mii_read(adapter, reg, &tmp); 1531 1532 status = -EIO; 1533 } 1534 /* Stop the write operation */ 1535 writel(0, &mac->mii_mgmt_cmd); 1536 1537 /* 1538 * set the registers we touched back to the state at which we entered 1539 * this function 1540 */ 1541 writel(mii_addr, &mac->mii_mgmt_addr); 1542 writel(mii_cmd, &mac->mii_mgmt_cmd); 1543 1544 return status; 1545} 1546 1547/* Still used from _mac for BIT_READ */ 1548static void et1310_phy_access_mii_bit(struct et131x_adapter *adapter, 1549 u16 action, u16 regnum, u16 bitnum, 1550 u8 *value) 1551{ 1552 u16 reg; 1553 u16 mask = 0x0001 << bitnum; 1554 1555 /* Read the requested register */ 1556 et131x_mii_read(adapter, regnum, &reg); 1557 1558 switch (action) { 1559 case TRUEPHY_BIT_READ: 1560 *value = (reg & mask) >> bitnum; 1561 break; 1562 1563 case TRUEPHY_BIT_SET: 1564 et131x_mii_write(adapter, regnum, reg | mask); 1565 break; 1566 1567 case TRUEPHY_BIT_CLEAR: 1568 et131x_mii_write(adapter, regnum, reg & ~mask); 1569 break; 1570 1571 default: 1572 break; 1573 } 1574} 1575 1576static void et1310_config_flow_control(struct et131x_adapter *adapter) 1577{ 1578 struct phy_device *phydev = adapter->phydev; 1579 1580 if (phydev->duplex == DUPLEX_HALF) { 1581 adapter->flowcontrol = FLOW_NONE; 1582 } else { 1583 char remote_pause, remote_async_pause; 1584 1585 et1310_phy_access_mii_bit(adapter, 1586 TRUEPHY_BIT_READ, 5, 10, &remote_pause); 1587 et1310_phy_access_mii_bit(adapter, 1588 TRUEPHY_BIT_READ, 5, 11, 1589 &remote_async_pause); 1590 1591 if ((remote_pause == TRUEPHY_BIT_SET) && 1592 (remote_async_pause == TRUEPHY_BIT_SET)) { 1593 adapter->flowcontrol = adapter->wanted_flow; 1594 } else if ((remote_pause == TRUEPHY_BIT_SET) && 1595 (remote_async_pause == TRUEPHY_BIT_CLEAR)) { 1596 if (adapter->wanted_flow == FLOW_BOTH) 1597 adapter->flowcontrol = FLOW_BOTH; 1598 else 1599 adapter->flowcontrol = FLOW_NONE; 1600 } else if ((remote_pause == TRUEPHY_BIT_CLEAR) && 1601 (remote_async_pause == TRUEPHY_BIT_CLEAR)) { 1602 adapter->flowcontrol = FLOW_NONE; 1603 } else {/* if (remote_pause == TRUEPHY_CLEAR_BIT && 1604 remote_async_pause == TRUEPHY_SET_BIT) */ 1605 if (adapter->wanted_flow == FLOW_BOTH) 1606 adapter->flowcontrol = FLOW_RXONLY; 1607 else 1608 adapter->flowcontrol = FLOW_NONE; 1609 } 1610 } 1611} 1612 1613/** 1614 * et1310_update_macstat_host_counters - Update the local copy of the statistics 1615 * @adapter: pointer to the adapter structure 1616 */ 1617static void et1310_update_macstat_host_counters(struct et131x_adapter *adapter) 1618{ 1619 struct ce_stats *stats = &adapter->stats; 1620 struct macstat_regs __iomem *macstat = 1621 &adapter->regs->macstat; 1622 1623 stats->tx_collisions += readl(&macstat->tx_total_collisions); 1624 stats->tx_first_collisions += readl(&macstat->tx_single_collisions); 1625 stats->tx_deferred += readl(&macstat->tx_deferred); 1626 stats->tx_excessive_collisions += 1627 readl(&macstat->tx_multiple_collisions); 1628 stats->tx_late_collisions += readl(&macstat->tx_late_collisions); 1629 stats->tx_underflows += readl(&macstat->tx_undersize_frames); 1630 stats->tx_max_pkt_errs += readl(&macstat->tx_oversize_frames); 1631 1632 stats->rx_align_errs += readl(&macstat->rx_align_errs); 1633 stats->rx_crc_errs += readl(&macstat->rx_code_errs); 1634 stats->rcvd_pkts_dropped += readl(&macstat->rx_drops); 1635 stats->rx_overflows += readl(&macstat->rx_oversize_packets); 1636 stats->rx_code_violations += readl(&macstat->rx_fcs_errs); 1637 stats->rx_length_errs += readl(&macstat->rx_frame_len_errs); 1638 stats->rx_other_errs += readl(&macstat->rx_fragment_packets); 1639} 1640 1641/** 1642 * et1310_handle_macstat_interrupt 1643 * @adapter: pointer to the adapter structure 1644 * 1645 * One of the MACSTAT counters has wrapped. Update the local copy of 1646 * the statistics held in the adapter structure, checking the "wrap" 1647 * bit for each counter. 1648 */ 1649static void et1310_handle_macstat_interrupt(struct et131x_adapter *adapter) 1650{ 1651 u32 carry_reg1; 1652 u32 carry_reg2; 1653 1654 /* Read the interrupt bits from the register(s). These are Clear On 1655 * Write. 1656 */ 1657 carry_reg1 = readl(&adapter->regs->macstat.carry_reg1); 1658 carry_reg2 = readl(&adapter->regs->macstat.carry_reg2); 1659 1660 writel(carry_reg1, &adapter->regs->macstat.carry_reg1); 1661 writel(carry_reg2, &adapter->regs->macstat.carry_reg2); 1662 1663 /* We need to do update the host copy of all the MAC_STAT counters. 1664 * For each counter, check it's overflow bit. If the overflow bit is 1665 * set, then increment the host version of the count by one complete 1666 * revolution of the counter. This routine is called when the counter 1667 * block indicates that one of the counters has wrapped. 1668 */ 1669 if (carry_reg1 & (1 << 14)) 1670 adapter->stats.rx_code_violations += COUNTER_WRAP_16_BIT; 1671 if (carry_reg1 & (1 << 8)) 1672 adapter->stats.rx_align_errs += COUNTER_WRAP_12_BIT; 1673 if (carry_reg1 & (1 << 7)) 1674 adapter->stats.rx_length_errs += COUNTER_WRAP_16_BIT; 1675 if (carry_reg1 & (1 << 2)) 1676 adapter->stats.rx_other_errs += COUNTER_WRAP_16_BIT; 1677 if (carry_reg1 & (1 << 6)) 1678 adapter->stats.rx_crc_errs += COUNTER_WRAP_16_BIT; 1679 if (carry_reg1 & (1 << 3)) 1680 adapter->stats.rx_overflows += COUNTER_WRAP_16_BIT; 1681 if (carry_reg1 & (1 << 0)) 1682 adapter->stats.rcvd_pkts_dropped += COUNTER_WRAP_16_BIT; 1683 if (carry_reg2 & (1 << 16)) 1684 adapter->stats.tx_max_pkt_errs += COUNTER_WRAP_12_BIT; 1685 if (carry_reg2 & (1 << 15)) 1686 adapter->stats.tx_underflows += COUNTER_WRAP_12_BIT; 1687 if (carry_reg2 & (1 << 6)) 1688 adapter->stats.tx_first_collisions += COUNTER_WRAP_12_BIT; 1689 if (carry_reg2 & (1 << 8)) 1690 adapter->stats.tx_deferred += COUNTER_WRAP_12_BIT; 1691 if (carry_reg2 & (1 << 5)) 1692 adapter->stats.tx_excessive_collisions += COUNTER_WRAP_12_BIT; 1693 if (carry_reg2 & (1 << 4)) 1694 adapter->stats.tx_late_collisions += COUNTER_WRAP_12_BIT; 1695 if (carry_reg2 & (1 << 2)) 1696 adapter->stats.tx_collisions += COUNTER_WRAP_12_BIT; 1697} 1698 1699static int et131x_mdio_read(struct mii_bus *bus, int phy_addr, int reg) 1700{ 1701 struct net_device *netdev = bus->priv; 1702 struct et131x_adapter *adapter = netdev_priv(netdev); 1703 u16 value; 1704 int ret; 1705 1706 ret = et131x_phy_mii_read(adapter, phy_addr, reg, &value); 1707 1708 if (ret < 0) 1709 return ret; 1710 else 1711 return value; 1712} 1713 1714static int et131x_mdio_write(struct mii_bus *bus, int phy_addr, 1715 int reg, u16 value) 1716{ 1717 struct net_device *netdev = bus->priv; 1718 struct et131x_adapter *adapter = netdev_priv(netdev); 1719 1720 return et131x_mii_write(adapter, reg, value); 1721} 1722 1723static int et131x_mdio_reset(struct mii_bus *bus) 1724{ 1725 struct net_device *netdev = bus->priv; 1726 struct et131x_adapter *adapter = netdev_priv(netdev); 1727 1728 et131x_mii_write(adapter, MII_BMCR, BMCR_RESET); 1729 1730 return 0; 1731} 1732 1733/** 1734 * et1310_phy_power_down - PHY power control 1735 * @adapter: device to control 1736 * @down: true for off/false for back on 1737 * 1738 * one hundred, ten, one thousand megs 1739 * How would you like to have your LAN accessed 1740 * Can't you see that this code processed 1741 * Phy power, phy power.. 1742 */ 1743static void et1310_phy_power_down(struct et131x_adapter *adapter, bool down) 1744{ 1745 u16 data; 1746 1747 et131x_mii_read(adapter, MII_BMCR, &data); 1748 data &= ~BMCR_PDOWN; 1749 if (down) 1750 data |= BMCR_PDOWN; 1751 et131x_mii_write(adapter, MII_BMCR, data); 1752} 1753 1754/** 1755 * et131x_xcvr_init - Init the phy if we are setting it into force mode 1756 * @adapter: pointer to our private adapter structure 1757 * 1758 */ 1759static void et131x_xcvr_init(struct et131x_adapter *adapter) 1760{ 1761 u16 imr; 1762 u16 isr; 1763 u16 lcr2; 1764 1765 et131x_mii_read(adapter, PHY_INTERRUPT_STATUS, &isr); 1766 et131x_mii_read(adapter, PHY_INTERRUPT_MASK, &imr); 1767 1768 /* Set the link status interrupt only. Bad behavior when link status 1769 * and auto neg are set, we run into a nested interrupt problem 1770 */ 1771 imr |= (ET_PHY_INT_MASK_AUTONEGSTAT | 1772 ET_PHY_INT_MASK_LINKSTAT | 1773 ET_PHY_INT_MASK_ENABLE); 1774 1775 et131x_mii_write(adapter, PHY_INTERRUPT_MASK, imr); 1776 1777 /* Set the LED behavior such that LED 1 indicates speed (off = 1778 * 10Mbits, blink = 100Mbits, on = 1000Mbits) and LED 2 indicates 1779 * link and activity (on for link, blink off for activity). 1780 * 1781 * NOTE: Some customizations have been added here for specific 1782 * vendors; The LED behavior is now determined by vendor data in the 1783 * EEPROM. However, the above description is the default. 1784 */ 1785 if ((adapter->eeprom_data[1] & 0x4) == 0) { 1786 et131x_mii_read(adapter, PHY_LED_2, &lcr2); 1787 1788 lcr2 &= (ET_LED2_LED_100TX | ET_LED2_LED_1000T); 1789 lcr2 |= (LED_VAL_LINKON_ACTIVE << LED_LINK_SHIFT); 1790 1791 if ((adapter->eeprom_data[1] & 0x8) == 0) 1792 lcr2 |= (LED_VAL_1000BT_100BTX << LED_TXRX_SHIFT); 1793 else 1794 lcr2 |= (LED_VAL_LINKON << LED_TXRX_SHIFT); 1795 1796 et131x_mii_write(adapter, PHY_LED_2, lcr2); 1797 } 1798} 1799 1800/** 1801 * et131x_configure_global_regs - configure JAGCore global regs 1802 * @adapter: pointer to our adapter structure 1803 * 1804 * Used to configure the global registers on the JAGCore 1805 */ 1806static void et131x_configure_global_regs(struct et131x_adapter *adapter) 1807{ 1808 struct global_regs __iomem *regs = &adapter->regs->global; 1809 1810 writel(0, &regs->rxq_start_addr); 1811 writel(INTERNAL_MEM_SIZE - 1, &regs->txq_end_addr); 1812 1813 if (adapter->registry_jumbo_packet < 2048) { 1814 /* Tx / RxDMA and Tx/Rx MAC interfaces have a 1k word 1815 * block of RAM that the driver can split between Tx 1816 * and Rx as it desires. Our default is to split it 1817 * 50/50: 1818 */ 1819 writel(PARM_RX_MEM_END_DEF, &regs->rxq_end_addr); 1820 writel(PARM_RX_MEM_END_DEF + 1, &regs->txq_start_addr); 1821 } else if (adapter->registry_jumbo_packet < 8192) { 1822 /* For jumbo packets > 2k but < 8k, split 50-50. */ 1823 writel(INTERNAL_MEM_RX_OFFSET, &regs->rxq_end_addr); 1824 writel(INTERNAL_MEM_RX_OFFSET + 1, &regs->txq_start_addr); 1825 } else { 1826 /* 9216 is the only packet size greater than 8k that 1827 * is available. The Tx buffer has to be big enough 1828 * for one whole packet on the Tx side. We'll make 1829 * the Tx 9408, and give the rest to Rx 1830 */ 1831 writel(0x01b3, &regs->rxq_end_addr); 1832 writel(0x01b4, &regs->txq_start_addr); 1833 } 1834 1835 /* Initialize the loopback register. Disable all loopbacks. */ 1836 writel(0, &regs->loopback); 1837 1838 /* MSI Register */ 1839 writel(0, &regs->msi_config); 1840 1841 /* By default, disable the watchdog timer. It will be enabled when 1842 * a packet is queued. 1843 */ 1844 writel(0, &regs->watchdog_timer); 1845} 1846 1847/** 1848 * et131x_config_rx_dma_regs - Start of Rx_DMA init sequence 1849 * @adapter: pointer to our adapter structure 1850 */ 1851static void et131x_config_rx_dma_regs(struct et131x_adapter *adapter) 1852{ 1853 struct rxdma_regs __iomem *rx_dma = &adapter->regs->rxdma; 1854 struct rx_ring *rx_local = &adapter->rx_ring; 1855 struct fbr_desc *fbr_entry; 1856 u32 entry; 1857 u32 psr_num_des; 1858 unsigned long flags; 1859 1860 /* Halt RXDMA to perform the reconfigure. */ 1861 et131x_rx_dma_disable(adapter); 1862 1863 /* Load the completion writeback physical address 1864 * 1865 * NOTE : dma_alloc_coherent(), used above to alloc DMA regions, 1866 * ALWAYS returns SAC (32-bit) addresses. If DAC (64-bit) addresses 1867 * are ever returned, make sure the high part is retrieved here 1868 * before storing the adjusted address. 1869 */ 1870 writel((u32) ((u64)rx_local->rx_status_bus >> 32), 1871 &rx_dma->dma_wb_base_hi); 1872 writel((u32) rx_local->rx_status_bus, &rx_dma->dma_wb_base_lo); 1873 1874 memset(rx_local->rx_status_block, 0, sizeof(struct rx_status_block)); 1875 1876 /* Set the address and parameters of the packet status ring into the 1877 * 1310's registers 1878 */ 1879 writel((u32) ((u64)rx_local->ps_ring_physaddr >> 32), 1880 &rx_dma->psr_base_hi); 1881 writel((u32) rx_local->ps_ring_physaddr, &rx_dma->psr_base_lo); 1882 writel(rx_local->psr_num_entries - 1, &rx_dma->psr_num_des); 1883 writel(0, &rx_dma->psr_full_offset); 1884 1885 psr_num_des = readl(&rx_dma->psr_num_des) & 0xFFF; 1886 writel((psr_num_des * LO_MARK_PERCENT_FOR_PSR) / 100, 1887 &rx_dma->psr_min_des); 1888 1889 spin_lock_irqsave(&adapter->rcv_lock, flags); 1890 1891 /* These local variables track the PSR in the adapter structure */ 1892 rx_local->local_psr_full = 0; 1893 1894 /* Now's the best time to initialize FBR1 contents */ 1895 fbr_entry = (struct fbr_desc *) rx_local->fbr[0]->ring_virtaddr; 1896 for (entry = 0; entry < rx_local->fbr[0]->num_entries; entry++) { 1897 fbr_entry->addr_hi = rx_local->fbr[0]->bus_high[entry]; 1898 fbr_entry->addr_lo = rx_local->fbr[0]->bus_low[entry]; 1899 fbr_entry->word2 = entry; 1900 fbr_entry++; 1901 } 1902 1903 /* Set the address and parameters of Free buffer ring 1 (and 0 if 1904 * required) into the 1310's registers 1905 */ 1906 writel((u32) (rx_local->fbr[0]->real_physaddr >> 32), 1907 &rx_dma->fbr1_base_hi); 1908 writel((u32) rx_local->fbr[0]->real_physaddr, &rx_dma->fbr1_base_lo); 1909 writel(rx_local->fbr[0]->num_entries - 1, &rx_dma->fbr1_num_des); 1910 writel(ET_DMA10_WRAP, &rx_dma->fbr1_full_offset); 1911 1912 /* This variable tracks the free buffer ring 1 full position, so it 1913 * has to match the above. 1914 */ 1915 rx_local->fbr[0]->local_full = ET_DMA10_WRAP; 1916 writel( 1917 ((rx_local->fbr[0]->num_entries * LO_MARK_PERCENT_FOR_RX) / 100) - 1, 1918 &rx_dma->fbr1_min_des); 1919 1920#ifdef USE_FBR0 1921 /* Now's the best time to initialize FBR0 contents */ 1922 fbr_entry = (struct fbr_desc *) rx_local->fbr[1]->ring_virtaddr; 1923 for (entry = 0; entry < rx_local->fbr[1]->num_entries; entry++) { 1924 fbr_entry->addr_hi = rx_local->fbr[1]->bus_high[entry]; 1925 fbr_entry->addr_lo = rx_local->fbr[1]->bus_low[entry]; 1926 fbr_entry->word2 = entry; 1927 fbr_entry++; 1928 } 1929 1930 writel((u32) (rx_local->fbr[1]->real_physaddr >> 32), 1931 &rx_dma->fbr0_base_hi); 1932 writel((u32) rx_local->fbr[1]->real_physaddr, &rx_dma->fbr0_base_lo); 1933 writel(rx_local->fbr[1]->num_entries - 1, &rx_dma->fbr0_num_des); 1934 writel(ET_DMA10_WRAP, &rx_dma->fbr0_full_offset); 1935 1936 /* This variable tracks the free buffer ring 0 full position, so it 1937 * has to match the above. 1938 */ 1939 rx_local->fbr[1]->local_full = ET_DMA10_WRAP; 1940 writel( 1941 ((rx_local->fbr[1]->num_entries * LO_MARK_PERCENT_FOR_RX) / 100) - 1, 1942 &rx_dma->fbr0_min_des); 1943#endif 1944 1945 /* Program the number of packets we will receive before generating an 1946 * interrupt. 1947 * For version B silicon, this value gets updated once autoneg is 1948 *complete. 1949 */ 1950 writel(PARM_RX_NUM_BUFS_DEF, &rx_dma->num_pkt_done); 1951 1952 /* The "time_done" is not working correctly to coalesce interrupts 1953 * after a given time period, but rather is giving us an interrupt 1954 * regardless of whether we have received packets. 1955 * This value gets updated once autoneg is complete. 1956 */ 1957 writel(PARM_RX_TIME_INT_DEF, &rx_dma->max_pkt_time); 1958 1959 spin_unlock_irqrestore(&adapter->rcv_lock, flags); 1960} 1961 1962/** 1963 * et131x_config_tx_dma_regs - Set up the tx dma section of the JAGCore. 1964 * @adapter: pointer to our private adapter structure 1965 * 1966 * Configure the transmit engine with the ring buffers we have created 1967 * and prepare it for use. 1968 */ 1969static void et131x_config_tx_dma_regs(struct et131x_adapter *adapter) 1970{ 1971 struct txdma_regs __iomem *txdma = &adapter->regs->txdma; 1972 1973 /* Load the hardware with the start of the transmit descriptor ring. */ 1974 writel((u32) ((u64)adapter->tx_ring.tx_desc_ring_pa >> 32), 1975 &txdma->pr_base_hi); 1976 writel((u32) adapter->tx_ring.tx_desc_ring_pa, 1977 &txdma->pr_base_lo); 1978 1979 /* Initialise the transmit DMA engine */ 1980 writel(NUM_DESC_PER_RING_TX - 1, &txdma->pr_num_des); 1981 1982 /* Load the completion writeback physical address */ 1983 writel((u32)((u64)adapter->tx_ring.tx_status_pa >> 32), 1984 &txdma->dma_wb_base_hi); 1985 writel((u32)adapter->tx_ring.tx_status_pa, &txdma->dma_wb_base_lo); 1986 1987 *adapter->tx_ring.tx_status = 0; 1988 1989 writel(0, &txdma->service_request); 1990 adapter->tx_ring.send_idx = 0; 1991} 1992 1993/** 1994 * et131x_adapter_setup - Set the adapter up as per cassini+ documentation 1995 * @adapter: pointer to our private adapter structure 1996 * 1997 * Returns 0 on success, errno on failure (as defined in errno.h) 1998 */ 1999static void et131x_adapter_setup(struct et131x_adapter *adapter) 2000{ 2001 /* Configure the JAGCore */ 2002 et131x_configure_global_regs(adapter); 2003 2004 et1310_config_mac_regs1(adapter); 2005 2006 /* Configure the MMC registers */ 2007 /* All we need to do is initialize the Memory Control Register */ 2008 writel(ET_MMC_ENABLE, &adapter->regs->mmc.mmc_ctrl); 2009 2010 et1310_config_rxmac_regs(adapter); 2011 et1310_config_txmac_regs(adapter); 2012 2013 et131x_config_rx_dma_regs(adapter); 2014 et131x_config_tx_dma_regs(adapter); 2015 2016 et1310_config_macstat_regs(adapter); 2017 2018 et1310_phy_power_down(adapter, 0); 2019 et131x_xcvr_init(adapter); 2020} 2021 2022/** 2023 * et131x_soft_reset - Issue a soft reset to the hardware, complete for ET1310 2024 * @adapter: pointer to our private adapter structure 2025 */ 2026static void et131x_soft_reset(struct et131x_adapter *adapter) 2027{ 2028 /* Disable MAC Core */ 2029 writel(0xc00f0000, &adapter->regs->mac.cfg1); 2030 2031 /* Set everything to a reset value */ 2032 writel(0x7F, &adapter->regs->global.sw_reset); 2033 writel(0x000f0000, &adapter->regs->mac.cfg1); 2034 writel(0x00000000, &adapter->regs->mac.cfg1); 2035} 2036 2037/** 2038 * et131x_enable_interrupts - enable interrupt 2039 * @adapter: et131x device 2040 * 2041 * Enable the appropriate interrupts on the ET131x according to our 2042 * configuration 2043 */ 2044static void et131x_enable_interrupts(struct et131x_adapter *adapter) 2045{ 2046 u32 mask; 2047 2048 /* Enable all global interrupts */ 2049 if (adapter->flowcontrol == FLOW_TXONLY || 2050 adapter->flowcontrol == FLOW_BOTH) 2051 mask = INT_MASK_ENABLE; 2052 else 2053 mask = INT_MASK_ENABLE_NO_FLOW; 2054 2055 writel(mask, &adapter->regs->global.int_mask); 2056} 2057 2058/** 2059 * et131x_disable_interrupts - interrupt disable 2060 * @adapter: et131x device 2061 * 2062 * Block all interrupts from the et131x device at the device itself 2063 */ 2064static void et131x_disable_interrupts(struct et131x_adapter *adapter) 2065{ 2066 /* Disable all global interrupts */ 2067 writel(INT_MASK_DISABLE, &adapter->regs->global.int_mask); 2068} 2069 2070/** 2071 * et131x_tx_dma_disable - Stop of Tx_DMA on the ET1310 2072 * @adapter: pointer to our adapter structure 2073 */ 2074static void et131x_tx_dma_disable(struct et131x_adapter *adapter) 2075{ 2076 /* Setup the tramsmit dma configuration register */ 2077 writel(ET_TXDMA_CSR_HALT|ET_TXDMA_SNGL_EPKT, 2078 &adapter->regs->txdma.csr); 2079} 2080 2081/** 2082 * et131x_enable_txrx - Enable tx/rx queues 2083 * @netdev: device to be enabled 2084 */ 2085static void et131x_enable_txrx(struct net_device *netdev) 2086{ 2087 struct et131x_adapter *adapter = netdev_priv(netdev); 2088 2089 /* Enable the Tx and Rx DMA engines (if not already enabled) */ 2090 et131x_rx_dma_enable(adapter); 2091 et131x_tx_dma_enable(adapter); 2092 2093 /* Enable device interrupts */ 2094 if (adapter->flags & fMP_ADAPTER_INTERRUPT_IN_USE) 2095 et131x_enable_interrupts(adapter); 2096 2097 /* We're ready to move some data, so start the queue */ 2098 netif_start_queue(netdev); 2099} 2100 2101/** 2102 * et131x_disable_txrx - Disable tx/rx queues 2103 * @netdev: device to be disabled 2104 */ 2105static void et131x_disable_txrx(struct net_device *netdev) 2106{ 2107 struct et131x_adapter *adapter = netdev_priv(netdev); 2108 2109 /* First thing is to stop the queue */ 2110 netif_stop_queue(netdev); 2111 2112 /* Stop the Tx and Rx DMA engines */ 2113 et131x_rx_dma_disable(adapter); 2114 et131x_tx_dma_disable(adapter); 2115 2116 /* Disable device interrupts */ 2117 et131x_disable_interrupts(adapter); 2118} 2119 2120/** 2121 * et131x_init_send - Initialize send data structures 2122 * @adapter: pointer to our private adapter structure 2123 */ 2124static void et131x_init_send(struct et131x_adapter *adapter) 2125{ 2126 struct tcb *tcb; 2127 u32 ct; 2128 struct tx_ring *tx_ring; 2129 2130 /* Setup some convenience pointers */ 2131 tx_ring = &adapter->tx_ring; 2132 tcb = adapter->tx_ring.tcb_ring; 2133 2134 tx_ring->tcb_qhead = tcb; 2135 2136 memset(tcb, 0, sizeof(struct tcb) * NUM_TCB); 2137 2138 /* Go through and set up each TCB */ 2139 for (ct = 0; ct++ < NUM_TCB; tcb++) 2140 /* Set the link pointer in HW TCB to the next TCB in the 2141 * chain 2142 */ 2143 tcb->next = tcb + 1; 2144 2145 /* Set the tail pointer */ 2146 tcb--; 2147 tx_ring->tcb_qtail = tcb; 2148 tcb->next = NULL; 2149 /* Curr send queue should now be empty */ 2150 tx_ring->send_head = NULL; 2151 tx_ring->send_tail = NULL; 2152} 2153 2154/** 2155 * et1310_enable_phy_coma - called when network cable is unplugged 2156 * @adapter: pointer to our adapter structure 2157 * 2158 * driver receive an phy status change interrupt while in D0 and check that 2159 * phy_status is down. 2160 * 2161 * -- gate off JAGCore; 2162 * -- set gigE PHY in Coma mode 2163 * -- wake on phy_interrupt; Perform software reset JAGCore, 2164 * re-initialize jagcore and gigE PHY 2165 * 2166 * Add D0-ASPM-PhyLinkDown Support: 2167 * -- while in D0, when there is a phy_interrupt indicating phy link 2168 * down status, call the MPSetPhyComa routine to enter this active 2169 * state power saving mode 2170 * -- while in D0-ASPM-PhyLinkDown mode, when there is a phy_interrupt 2171 * indicating linkup status, call the MPDisablePhyComa routine to 2172 * restore JAGCore and gigE PHY 2173 */ 2174static void et1310_enable_phy_coma(struct et131x_adapter *adapter) 2175{ 2176 unsigned long flags; 2177 u32 pmcsr; 2178 2179 pmcsr = readl(&adapter->regs->global.pm_csr); 2180 2181 /* Save the GbE PHY speed and duplex modes. Need to restore this 2182 * when cable is plugged back in 2183 */ 2184 /* 2185 * TODO - when PM is re-enabled, check if we need to 2186 * perform a similar task as this - 2187 * adapter->pdown_speed = adapter->ai_force_speed; 2188 * adapter->pdown_duplex = adapter->ai_force_duplex; 2189 */ 2190 2191 /* Stop sending packets. */ 2192 spin_lock_irqsave(&adapter->send_hw_lock, flags); 2193 adapter->flags |= fMP_ADAPTER_LOWER_POWER; 2194 spin_unlock_irqrestore(&adapter->send_hw_lock, flags); 2195 2196 /* Wait for outstanding Receive packets */ 2197 2198 et131x_disable_txrx(adapter->netdev); 2199 2200 /* Gate off JAGCore 3 clock domains */ 2201 pmcsr &= ~ET_PMCSR_INIT; 2202 writel(pmcsr, &adapter->regs->global.pm_csr); 2203 2204 /* Program gigE PHY in to Coma mode */ 2205 pmcsr |= ET_PM_PHY_SW_COMA; 2206 writel(pmcsr, &adapter->regs->global.pm_csr); 2207} 2208 2209/** 2210 * et1310_disable_phy_coma - Disable the Phy Coma Mode 2211 * @adapter: pointer to our adapter structure 2212 */ 2213static void et1310_disable_phy_coma(struct et131x_adapter *adapter) 2214{ 2215 u32 pmcsr; 2216 2217 pmcsr = readl(&adapter->regs->global.pm_csr); 2218 2219 /* Disable phy_sw_coma register and re-enable JAGCore clocks */ 2220 pmcsr |= ET_PMCSR_INIT; 2221 pmcsr &= ~ET_PM_PHY_SW_COMA; 2222 writel(pmcsr, &adapter->regs->global.pm_csr); 2223 2224 /* Restore the GbE PHY speed and duplex modes; 2225 * Reset JAGCore; re-configure and initialize JAGCore and gigE PHY 2226 */ 2227 /* TODO - when PM is re-enabled, check if we need to 2228 * perform a similar task as this - 2229 * adapter->ai_force_speed = adapter->pdown_speed; 2230 * adapter->ai_force_duplex = adapter->pdown_duplex; 2231 */ 2232 2233 /* Re-initialize the send structures */ 2234 et131x_init_send(adapter); 2235 2236 /* Bring the device back to the state it was during init prior to 2237 * autonegotiation being complete. This way, when we get the auto-neg 2238 * complete interrupt, we can complete init by calling ConfigMacREGS2. 2239 */ 2240 et131x_soft_reset(adapter); 2241 2242 /* setup et1310 as per the documentation ?? */ 2243 et131x_adapter_setup(adapter); 2244 2245 /* Allow Tx to restart */ 2246 adapter->flags &= ~fMP_ADAPTER_LOWER_POWER; 2247 2248 et131x_enable_txrx(adapter->netdev); 2249} 2250 2251static inline u32 bump_free_buff_ring(u32 *free_buff_ring, u32 limit) 2252{ 2253 u32 tmp_free_buff_ring = *free_buff_ring; 2254 tmp_free_buff_ring++; 2255 /* This works for all cases where limit < 1024. The 1023 case 2256 works because 1023++ is 1024 which means the if condition is not 2257 taken but the carry of the bit into the wrap bit toggles the wrap 2258 value correctly */ 2259 if ((tmp_free_buff_ring & ET_DMA10_MASK) > limit) { 2260 tmp_free_buff_ring &= ~ET_DMA10_MASK; 2261 tmp_free_buff_ring ^= ET_DMA10_WRAP; 2262 } 2263 /* For the 1023 case */ 2264 tmp_free_buff_ring &= (ET_DMA10_MASK|ET_DMA10_WRAP); 2265 *free_buff_ring = tmp_free_buff_ring; 2266 return tmp_free_buff_ring; 2267} 2268 2269/** 2270 * et131x_align_allocated_memory - Align allocated memory on a given boundary 2271 * @adapter: pointer to our adapter structure 2272 * @phys_addr: pointer to Physical address 2273 * @offset: pointer to the offset variable 2274 * @mask: correct mask 2275 */ 2276static void et131x_align_allocated_memory(struct et131x_adapter *adapter, 2277 u64 *phys_addr, u64 *offset, 2278 u64 mask) 2279{ 2280 u64 new_addr = *phys_addr & ~mask; 2281 2282 *offset = 0; 2283 2284 if (new_addr != *phys_addr) { 2285 /* Move to next aligned block */ 2286 new_addr += mask + 1; 2287 /* Return offset for adjusting virt addr */ 2288 *offset = new_addr - *phys_addr; 2289 /* Return new physical address */ 2290 *phys_addr = new_addr; 2291 } 2292} 2293 2294/** 2295 * et131x_rx_dma_memory_alloc 2296 * @adapter: pointer to our private adapter structure 2297 * 2298 * Returns 0 on success and errno on failure (as defined in errno.h) 2299 * 2300 * Allocates Free buffer ring 1 for sure, free buffer ring 0 if required, 2301 * and the Packet Status Ring. 2302 */ 2303static int et131x_rx_dma_memory_alloc(struct et131x_adapter *adapter) 2304{ 2305 u32 i, j; 2306 u32 bufsize; 2307 u32 pktstat_ringsize, fbr_chunksize; 2308 struct rx_ring *rx_ring; 2309 2310 /* Setup some convenience pointers */ 2311 rx_ring = &adapter->rx_ring; 2312 2313 /* Alloc memory for the lookup table */ 2314#ifdef USE_FBR0 2315 rx_ring->fbr[1] = kmalloc(sizeof(struct fbr_lookup), GFP_KERNEL); 2316#endif 2317 rx_ring->fbr[0] = kmalloc(sizeof(struct fbr_lookup), GFP_KERNEL); 2318 2319 /* The first thing we will do is configure the sizes of the buffer 2320 * rings. These will change based on jumbo packet support. Larger 2321 * jumbo packets increases the size of each entry in FBR0, and the 2322 * number of entries in FBR0, while at the same time decreasing the 2323 * number of entries in FBR1. 2324 * 2325 * FBR1 holds "large" frames, FBR0 holds "small" frames. If FBR1 2326 * entries are huge in order to accommodate a "jumbo" frame, then it 2327 * will have less entries. Conversely, FBR1 will now be relied upon 2328 * to carry more "normal" frames, thus it's entry size also increases 2329 * and the number of entries goes up too (since it now carries 2330 * "small" + "regular" packets. 2331 * 2332 * In this scheme, we try to maintain 512 entries between the two 2333 * rings. Also, FBR1 remains a constant size - when it's size doubles 2334 * the number of entries halves. FBR0 increases in size, however. 2335 */ 2336 2337 if (adapter->registry_jumbo_packet < 2048) { 2338#ifdef USE_FBR0 2339 rx_ring->fbr[1]->buffsize = 256; 2340 rx_ring->fbr[1]->num_entries = 512; 2341#endif 2342 rx_ring->fbr[0]->buffsize = 2048; 2343 rx_ring->fbr[0]->num_entries = 512; 2344 } else if (adapter->registry_jumbo_packet < 4096) { 2345#ifdef USE_FBR0 2346 rx_ring->fbr[1]->buffsize = 512; 2347 rx_ring->fbr[1]->num_entries = 1024; 2348#endif 2349 rx_ring->fbr[0]->buffsize = 4096; 2350 rx_ring->fbr[0]->num_entries = 512; 2351 } else { 2352#ifdef USE_FBR0 2353 rx_ring->fbr[1]->buffsize = 1024; 2354 rx_ring->fbr[1]->num_entries = 768; 2355#endif 2356 rx_ring->fbr[0]->buffsize = 16384; 2357 rx_ring->fbr[0]->num_entries = 128; 2358 } 2359 2360#ifdef USE_FBR0 2361 adapter->rx_ring.psr_num_entries = 2362 adapter->rx_ring.fbr[1]->num_entries + 2363 adapter->rx_ring.fbr[0]->num_entries; 2364#else 2365 adapter->rx_ring.psr_num_entries = adapter->rx_ring.fbr[0]->num_entries; 2366#endif 2367 2368 /* Allocate an area of memory for Free Buffer Ring 1 */ 2369 bufsize = (sizeof(struct fbr_desc) * rx_ring->fbr[0]->num_entries) + 2370 0xfff; 2371 rx_ring->fbr[0]->ring_virtaddr = dma_alloc_coherent(&adapter->pdev->dev, 2372 bufsize, 2373 &rx_ring->fbr[0]->ring_physaddr, 2374 GFP_KERNEL); 2375 if (!rx_ring->fbr[0]->ring_virtaddr) { 2376 dev_err(&adapter->pdev->dev, 2377 "Cannot alloc memory for Free Buffer Ring 1\n"); 2378 return -ENOMEM; 2379 } 2380 2381 /* Save physical address 2382 * 2383 * NOTE: dma_alloc_coherent(), used above to alloc DMA regions, 2384 * ALWAYS returns SAC (32-bit) addresses. If DAC (64-bit) addresses 2385 * are ever returned, make sure the high part is retrieved here 2386 * before storing the adjusted address. 2387 */ 2388 rx_ring->fbr[0]->real_physaddr = rx_ring->fbr[0]->ring_physaddr; 2389 2390 /* Align Free Buffer Ring 1 on a 4K boundary */ 2391 et131x_align_allocated_memory(adapter, 2392 &rx_ring->fbr[0]->real_physaddr, 2393 &rx_ring->fbr[0]->offset, 0x0FFF); 2394 2395 rx_ring->fbr[0]->ring_virtaddr = 2396 (void *)((u8 *) rx_ring->fbr[0]->ring_virtaddr + 2397 rx_ring->fbr[0]->offset); 2398 2399#ifdef USE_FBR0 2400 /* Allocate an area of memory for Free Buffer Ring 0 */ 2401 bufsize = (sizeof(struct fbr_desc) * rx_ring->fbr[1]->num_entries) + 2402 0xfff; 2403 rx_ring->fbr[1]->ring_virtaddr = dma_alloc_coherent(&adapter->pdev->dev, 2404 bufsize, 2405 &rx_ring->fbr[1]->ring_physaddr, 2406 GFP_KERNEL); 2407 if (!rx_ring->fbr[1]->ring_virtaddr) { 2408 dev_err(&adapter->pdev->dev, 2409 "Cannot alloc memory for Free Buffer Ring 0\n"); 2410 return -ENOMEM; 2411 } 2412 2413 /* Save physical address 2414 * 2415 * NOTE: dma_alloc_coherent(), used above to alloc DMA regions, 2416 * ALWAYS returns SAC (32-bit) addresses. If DAC (64-bit) addresses 2417 * are ever returned, make sure the high part is retrieved here before 2418 * storing the adjusted address. 2419 */ 2420 rx_ring->fbr[1]->real_physaddr = rx_ring->fbr[1]->ring_physaddr; 2421 2422 /* Align Free Buffer Ring 0 on a 4K boundary */ 2423 et131x_align_allocated_memory(adapter, 2424 &rx_ring->fbr[1]->real_physaddr, 2425 &rx_ring->fbr[1]->offset, 0x0FFF); 2426 2427 rx_ring->fbr[1]->ring_virtaddr = 2428 (void *)((u8 *) rx_ring->fbr[1]->ring_virtaddr + 2429 rx_ring->fbr[1]->offset); 2430#endif 2431 for (i = 0; i < (rx_ring->fbr[0]->num_entries / FBR_CHUNKS); i++) { 2432 u64 fbr1_tmp_physaddr; 2433 u64 fbr1_offset; 2434 u32 fbr1_align; 2435 2436 /* This code allocates an area of memory big enough for N 2437 * free buffers + (buffer_size - 1) so that the buffers can 2438 * be aligned on 4k boundaries. If each buffer were aligned 2439 * to a buffer_size boundary, the effect would be to double 2440 * the size of FBR0. By allocating N buffers at once, we 2441 * reduce this overhead. 2442 */ 2443 if (rx_ring->fbr[0]->buffsize > 4096) 2444 fbr1_align = 4096; 2445 else 2446 fbr1_align = rx_ring->fbr[0]->buffsize; 2447 2448 fbr_chunksize = 2449 (FBR_CHUNKS * rx_ring->fbr[0]->buffsize) + fbr1_align - 1; 2450 rx_ring->fbr[0]->mem_virtaddrs[i] = 2451 dma_alloc_coherent(&adapter->pdev->dev, fbr_chunksize, 2452 &rx_ring->fbr[0]->mem_physaddrs[i], 2453 GFP_KERNEL); 2454 2455 if (!rx_ring->fbr[0]->mem_virtaddrs[i]) { 2456 dev_err(&adapter->pdev->dev, 2457 "Could not alloc memory\n"); 2458 return -ENOMEM; 2459 } 2460 2461 /* See NOTE in "Save Physical Address" comment above */ 2462 fbr1_tmp_physaddr = rx_ring->fbr[0]->mem_physaddrs[i]; 2463 2464 et131x_align_allocated_memory(adapter, 2465 &fbr1_tmp_physaddr, 2466 &fbr1_offset, (fbr1_align - 1)); 2467 2468 for (j = 0; j < FBR_CHUNKS; j++) { 2469 u32 index = (i * FBR_CHUNKS) + j; 2470 2471 /* Save the Virtual address of this index for quick 2472 * access later 2473 */ 2474 rx_ring->fbr[0]->virt[index] = 2475 (u8 *) rx_ring->fbr[0]->mem_virtaddrs[i] + 2476 (j * rx_ring->fbr[0]->buffsize) + fbr1_offset; 2477 2478 /* now store the physical address in the descriptor 2479 * so the device can access it 2480 */ 2481 rx_ring->fbr[0]->bus_high[index] = 2482 (u32) (fbr1_tmp_physaddr >> 32); 2483 rx_ring->fbr[0]->bus_low[index] = 2484 (u32) fbr1_tmp_physaddr; 2485 2486 fbr1_tmp_physaddr += rx_ring->fbr[0]->buffsize; 2487 2488 rx_ring->fbr[0]->buffer1[index] = 2489 rx_ring->fbr[0]->virt[index]; 2490 rx_ring->fbr[0]->buffer2[index] = 2491 rx_ring->fbr[0]->virt[index] - 4; 2492 } 2493 } 2494 2495#ifdef USE_FBR0 2496 /* Same for FBR0 (if in use) */ 2497 for (i = 0; i < (rx_ring->fbr[1]->num_entries / FBR_CHUNKS); i++) { 2498 u64 fbr0_tmp_physaddr; 2499 u64 fbr0_offset; 2500 2501 fbr_chunksize = 2502 ((FBR_CHUNKS + 1) * rx_ring->fbr[1]->buffsize) - 1; 2503 rx_ring->fbr[1]->mem_virtaddrs[i] = 2504 dma_alloc_coherent(&adapter->pdev->dev, fbr_chunksize, 2505 &rx_ring->fbr[1]->mem_physaddrs[i], 2506 GFP_KERNEL); 2507 2508 if (!rx_ring->fbr[1]->mem_virtaddrs[i]) { 2509 dev_err(&adapter->pdev->dev, 2510 "Could not alloc memory\n"); 2511 return -ENOMEM; 2512 } 2513 2514 /* See NOTE in "Save Physical Address" comment above */ 2515 fbr0_tmp_physaddr = rx_ring->fbr[1]->mem_physaddrs[i]; 2516 2517 et131x_align_allocated_memory(adapter, 2518 &fbr0_tmp_physaddr, 2519 &fbr0_offset, 2520 rx_ring->fbr[1]->buffsize - 1); 2521 2522 for (j = 0; j < FBR_CHUNKS; j++) { 2523 u32 index = (i * FBR_CHUNKS) + j; 2524 2525 rx_ring->fbr[1]->virt[index] = 2526 (u8 *) rx_ring->fbr[1]->mem_virtaddrs[i] + 2527 (j * rx_ring->fbr[1]->buffsize) + fbr0_offset; 2528 2529 rx_ring->fbr[1]->bus_high[index] = 2530 (u32) (fbr0_tmp_physaddr >> 32); 2531 rx_ring->fbr[1]->bus_low[index] = 2532 (u32) fbr0_tmp_physaddr; 2533 2534 fbr0_tmp_physaddr += rx_ring->fbr[1]->buffsize; 2535 2536 rx_ring->fbr[1]->buffer1[index] = 2537 rx_ring->fbr[1]->virt[index]; 2538 rx_ring->fbr[1]->buffer2[index] = 2539 rx_ring->fbr[1]->virt[index] - 4; 2540 } 2541 } 2542#endif 2543 2544 /* Allocate an area of memory for FIFO of Packet Status ring entries */ 2545 pktstat_ringsize = 2546 sizeof(struct pkt_stat_desc) * adapter->rx_ring.psr_num_entries; 2547 2548 rx_ring->ps_ring_virtaddr = dma_alloc_coherent(&adapter->pdev->dev, 2549 pktstat_ringsize, 2550 &rx_ring->ps_ring_physaddr, 2551 GFP_KERNEL); 2552 2553 if (!rx_ring->ps_ring_virtaddr) { 2554 dev_err(&adapter->pdev->dev, 2555 "Cannot alloc memory for Packet Status Ring\n"); 2556 return -ENOMEM; 2557 } 2558 pr_info("Packet Status Ring %llx\n", 2559 (unsigned long long) rx_ring->ps_ring_physaddr); 2560 2561 /* 2562 * NOTE : dma_alloc_coherent(), used above to alloc DMA regions, 2563 * ALWAYS returns SAC (32-bit) addresses. If DAC (64-bit) addresses 2564 * are ever returned, make sure the high part is retrieved here before 2565 * storing the adjusted address. 2566 */ 2567 2568 /* Allocate an area of memory for writeback of status information */ 2569 rx_ring->rx_status_block = dma_alloc_coherent(&adapter->pdev->dev, 2570 sizeof(struct rx_status_block), 2571 &rx_ring->rx_status_bus, 2572 GFP_KERNEL); 2573 if (!rx_ring->rx_status_block) { 2574 dev_err(&adapter->pdev->dev, 2575 "Cannot alloc memory for Status Block\n"); 2576 return -ENOMEM; 2577 } 2578 rx_ring->num_rfd = NIC_DEFAULT_NUM_RFD; 2579 pr_info("PRS %llx\n", (unsigned long long)rx_ring->rx_status_bus); 2580 2581 /* Recv 2582 * kmem_cache_create initializes a lookaside list. After successful 2583 * creation, nonpaged fixed-size blocks can be allocated from and 2584 * freed to the lookaside list. 2585 * RFDs will be allocated from this pool. 2586 */ 2587 rx_ring->recv_lookaside = kmem_cache_create(adapter->netdev->name, 2588 sizeof(struct rfd), 2589 0, 2590 SLAB_CACHE_DMA | 2591 SLAB_HWCACHE_ALIGN, 2592 NULL); 2593 2594 adapter->flags |= fMP_ADAPTER_RECV_LOOKASIDE; 2595 2596 /* The RFDs are going to be put on lists later on, so initialize the 2597 * lists now. 2598 */ 2599 INIT_LIST_HEAD(&rx_ring->recv_list); 2600 return 0; 2601} 2602 2603/** 2604 * et131x_rx_dma_memory_free - Free all memory allocated within this module. 2605 * @adapter: pointer to our private adapter structure 2606 */ 2607static void et131x_rx_dma_memory_free(struct et131x_adapter *adapter) 2608{ 2609 u32 index; 2610 u32 bufsize; 2611 u32 pktstat_ringsize; 2612 struct rfd *rfd; 2613 struct rx_ring *rx_ring; 2614 2615 /* Setup some convenience pointers */ 2616 rx_ring = &adapter->rx_ring; 2617 2618 /* Free RFDs and associated packet descriptors */ 2619 WARN_ON(rx_ring->num_ready_recv != rx_ring->num_rfd); 2620 2621 while (!list_empty(&rx_ring->recv_list)) { 2622 rfd = (struct rfd *) list_entry(rx_ring->recv_list.next, 2623 struct rfd, list_node); 2624 2625 list_del(&rfd->list_node); 2626 rfd->skb = NULL; 2627 kmem_cache_free(adapter->rx_ring.recv_lookaside, rfd); 2628 } 2629 2630 /* Free Free Buffer Ring 1 */ 2631 if (rx_ring->fbr[0]->ring_virtaddr) { 2632 /* First the packet memory */ 2633 for (index = 0; index < 2634 (rx_ring->fbr[0]->num_entries / FBR_CHUNKS); index++) { 2635 if (rx_ring->fbr[0]->mem_virtaddrs[index]) { 2636 u32 fbr1_align; 2637 2638 if (rx_ring->fbr[0]->buffsize > 4096) 2639 fbr1_align = 4096; 2640 else 2641 fbr1_align = rx_ring->fbr[0]->buffsize; 2642 2643 bufsize = 2644 (rx_ring->fbr[0]->buffsize * FBR_CHUNKS) + 2645 fbr1_align - 1; 2646 2647 dma_free_coherent(&adapter->pdev->dev, 2648 bufsize, 2649 rx_ring->fbr[0]->mem_virtaddrs[index], 2650 rx_ring->fbr[0]->mem_physaddrs[index]); 2651 2652 rx_ring->fbr[0]->mem_virtaddrs[index] = NULL; 2653 } 2654 } 2655 2656 /* Now the FIFO itself */ 2657 rx_ring->fbr[0]->ring_virtaddr = (void *)((u8 *) 2658 rx_ring->fbr[0]->ring_virtaddr - rx_ring->fbr[0]->offset); 2659 2660 bufsize = 2661 (sizeof(struct fbr_desc) * rx_ring->fbr[0]->num_entries) + 2662 0xfff; 2663 2664 dma_free_coherent(&adapter->pdev->dev, bufsize, 2665 rx_ring->fbr[0]->ring_virtaddr, 2666 rx_ring->fbr[0]->ring_physaddr); 2667 2668 rx_ring->fbr[0]->ring_virtaddr = NULL; 2669 } 2670 2671#ifdef USE_FBR0 2672 /* Now the same for Free Buffer Ring 0 */ 2673 if (rx_ring->fbr[1]->ring_virtaddr) { 2674 /* First the packet memory */ 2675 for (index = 0; index < 2676 (rx_ring->fbr[1]->num_entries / FBR_CHUNKS); index++) { 2677 if (rx_ring->fbr[1]->mem_virtaddrs[index]) { 2678 bufsize = 2679 (rx_ring->fbr[1]->buffsize * 2680 (FBR_CHUNKS + 1)) - 1; 2681 2682 dma_free_coherent(&adapter->pdev->dev, 2683 bufsize, 2684 rx_ring->fbr[1]->mem_virtaddrs[index], 2685 rx_ring->fbr[1]->mem_physaddrs[index]); 2686 2687 rx_ring->fbr[1]->mem_virtaddrs[index] = NULL; 2688 } 2689 } 2690 2691 /* Now the FIFO itself */ 2692 rx_ring->fbr[1]->ring_virtaddr = (void *)((u8 *) 2693 rx_ring->fbr[1]->ring_virtaddr - rx_ring->fbr[1]->offset); 2694 2695 bufsize = 2696 (sizeof(struct fbr_desc) * rx_ring->fbr[1]->num_entries) + 2697 0xfff; 2698 2699 dma_free_coherent(&adapter->pdev->dev, 2700 bufsize, 2701 rx_ring->fbr[1]->ring_virtaddr, 2702 rx_ring->fbr[1]->ring_physaddr); 2703 2704 rx_ring->fbr[1]->ring_virtaddr = NULL; 2705 } 2706#endif 2707 2708 /* Free Packet Status Ring */ 2709 if (rx_ring->ps_ring_virtaddr) { 2710 pktstat_ringsize = 2711 sizeof(struct pkt_stat_desc) * 2712 adapter->rx_ring.psr_num_entries; 2713 2714 dma_free_coherent(&adapter->pdev->dev, pktstat_ringsize, 2715 rx_ring->ps_ring_virtaddr, 2716 rx_ring->ps_ring_physaddr); 2717 2718 rx_ring->ps_ring_virtaddr = NULL; 2719 } 2720 2721 /* Free area of memory for the writeback of status information */ 2722 if (rx_ring->rx_status_block) { 2723 dma_free_coherent(&adapter->pdev->dev, 2724 sizeof(struct rx_status_block), 2725 rx_ring->rx_status_block, rx_ring->rx_status_bus); 2726 rx_ring->rx_status_block = NULL; 2727 } 2728 2729 /* Destroy the lookaside (RFD) pool */ 2730 if (adapter->flags & fMP_ADAPTER_RECV_LOOKASIDE) { 2731 kmem_cache_destroy(rx_ring->recv_lookaside); 2732 adapter->flags &= ~fMP_ADAPTER_RECV_LOOKASIDE; 2733 } 2734 2735 /* Free the FBR Lookup Table */ 2736#ifdef USE_FBR0 2737 kfree(rx_ring->fbr[1]); 2738#endif 2739 2740 kfree(rx_ring->fbr[0]); 2741 2742 /* Reset Counters */ 2743 rx_ring->num_ready_recv = 0; 2744} 2745 2746/** 2747 * et131x_init_recv - Initialize receive data structures. 2748 * @adapter: pointer to our private adapter structure 2749 * 2750 * Returns 0 on success and errno on failure (as defined in errno.h) 2751 */ 2752static int et131x_init_recv(struct et131x_adapter *adapter) 2753{ 2754 int status = -ENOMEM; 2755 struct rfd *rfd = NULL; 2756 u32 rfdct; 2757 u32 numrfd = 0; 2758 struct rx_ring *rx_ring; 2759 2760 /* Setup some convenience pointers */ 2761 rx_ring = &adapter->rx_ring; 2762 2763 /* Setup each RFD */ 2764 for (rfdct = 0; rfdct < rx_ring->num_rfd; rfdct++) { 2765 rfd = kmem_cache_alloc(rx_ring->recv_lookaside, 2766 GFP_ATOMIC | GFP_DMA); 2767 2768 if (!rfd) { 2769 dev_err(&adapter->pdev->dev, 2770 "Couldn't alloc RFD out of kmem_cache\n"); 2771 status = -ENOMEM; 2772 continue; 2773 } 2774 2775 rfd->skb = NULL; 2776 2777 /* Add this RFD to the recv_list */ 2778 list_add_tail(&rfd->list_node, &rx_ring->recv_list); 2779 2780 /* Increment both the available RFD's, and the total RFD's. */ 2781 rx_ring->num_ready_recv++; 2782 numrfd++; 2783 } 2784 2785 if (numrfd > NIC_MIN_NUM_RFD) 2786 status = 0; 2787 2788 rx_ring->num_rfd = numrfd; 2789 2790 if (status != 0) { 2791 kmem_cache_free(rx_ring->recv_lookaside, rfd); 2792 dev_err(&adapter->pdev->dev, 2793 "Allocation problems in et131x_init_recv\n"); 2794 } 2795 return status; 2796} 2797 2798/** 2799 * et131x_set_rx_dma_timer - Set the heartbeat timer according to line rate. 2800 * @adapter: pointer to our adapter structure 2801 */ 2802static void et131x_set_rx_dma_timer(struct et131x_adapter *adapter) 2803{ 2804 struct phy_device *phydev = adapter->phydev; 2805 2806 if (!phydev) 2807 return; 2808 2809 /* For version B silicon, we do not use the RxDMA timer for 10 and 100 2810 * Mbits/s line rates. We do not enable and RxDMA interrupt coalescing. 2811 */ 2812 if ((phydev->speed == SPEED_100) || (phydev->speed == SPEED_10)) { 2813 writel(0, &adapter->regs->rxdma.max_pkt_time); 2814 writel(1, &adapter->regs->rxdma.num_pkt_done); 2815 } 2816} 2817 2818/** 2819 * NICReturnRFD - Recycle a RFD and put it back onto the receive list 2820 * @adapter: pointer to our adapter 2821 * @rfd: pointer to the RFD 2822 */ 2823static void nic_return_rfd(struct et131x_adapter *adapter, struct rfd *rfd) 2824{ 2825 struct rx_ring *rx_local = &adapter->rx_ring; 2826 struct rxdma_regs __iomem *rx_dma = &adapter->regs->rxdma; 2827 u16 buff_index = rfd->bufferindex; 2828 u8 ring_index = rfd->ringindex; 2829 unsigned long flags; 2830 2831 /* We don't use any of the OOB data besides status. Otherwise, we 2832 * need to clean up OOB data 2833 */ 2834 if ( 2835#ifdef USE_FBR0 2836 (ring_index == 0 && buff_index < rx_local->fbr[1]->num_entries) || 2837#endif 2838 (ring_index == 1 && buff_index < rx_local->fbr[0]->num_entries)) { 2839 spin_lock_irqsave(&adapter->fbr_lock, flags); 2840 2841 if (ring_index == 1) { 2842 struct fbr_desc *next = (struct fbr_desc *) 2843 (rx_local->fbr[0]->ring_virtaddr) + 2844 INDEX10(rx_local->fbr[0]->local_full); 2845 2846 /* Handle the Free Buffer Ring advancement here. Write 2847 * the PA / Buffer Index for the returned buffer into 2848 * the oldest (next to be freed)FBR entry 2849 */ 2850 next->addr_hi = rx_local->fbr[0]->bus_high[buff_index]; 2851 next->addr_lo = rx_local->fbr[0]->bus_low[buff_index]; 2852 next->word2 = buff_index; 2853 2854 writel(bump_free_buff_ring( 2855 &rx_local->fbr[0]->local_full, 2856 rx_local->fbr[0]->num_entries - 1), 2857 &rx_dma->fbr1_full_offset); 2858 } 2859#ifdef USE_FBR0 2860 else { 2861 struct fbr_desc *next = (struct fbr_desc *) 2862 rx_local->fbr[1]->ring_virtaddr + 2863 INDEX10(rx_local->fbr[1]->local_full); 2864 2865 /* Handle the Free Buffer Ring advancement here. Write 2866 * the PA / Buffer Index for the returned buffer into 2867 * the oldest (next to be freed) FBR entry 2868 */ 2869 next->addr_hi = rx_local->fbr[1]->bus_high[buff_index]; 2870 next->addr_lo = rx_local->fbr[1]->bus_low[buff_index]; 2871 next->word2 = buff_index; 2872 2873 writel(bump_free_buff_ring( 2874 &rx_local->fbr[1]->local_full, 2875 rx_local->fbr[1]->num_entries - 1), 2876 &rx_dma->fbr0_full_offset); 2877 } 2878#endif 2879 spin_unlock_irqrestore(&adapter->fbr_lock, flags); 2880 } else { 2881 dev_err(&adapter->pdev->dev, 2882 "%s illegal Buffer Index returned\n", __func__); 2883 } 2884 2885 /* The processing on this RFD is done, so put it back on the tail of 2886 * our list 2887 */ 2888 spin_lock_irqsave(&adapter->rcv_lock, flags); 2889 list_add_tail(&rfd->list_node, &rx_local->recv_list); 2890 rx_local->num_ready_recv++; 2891 spin_unlock_irqrestore(&adapter->rcv_lock, flags); 2892 2893 WARN_ON(rx_local->num_ready_recv > rx_local->num_rfd); 2894} 2895 2896/** 2897 * nic_rx_pkts - Checks the hardware for available packets 2898 * @adapter: pointer to our adapter 2899 * 2900 * Returns rfd, a pointer to our MPRFD. 2901 * 2902 * Checks the hardware for available packets, using completion ring 2903 * If packets are available, it gets an RFD from the recv_list, attaches 2904 * the packet to it, puts the RFD in the RecvPendList, and also returns 2905 * the pointer to the RFD. 2906 */ 2907static struct rfd *nic_rx_pkts(struct et131x_adapter *adapter) 2908{ 2909 struct rx_ring *rx_local = &adapter->rx_ring; 2910 struct rx_status_block *status; 2911 struct pkt_stat_desc *psr; 2912 struct rfd *rfd; 2913 u32 i; 2914 u8 *buf; 2915 unsigned long flags; 2916 struct list_head *element; 2917 u8 ring_index; 2918 u16 buff_index; 2919 u32 len; 2920 u32 word0; 2921 u32 word1; 2922 2923 /* RX Status block is written by the DMA engine prior to every 2924 * interrupt. It contains the next to be used entry in the Packet 2925 * Status Ring, and also the two Free Buffer rings. 2926 */ 2927 status = rx_local->rx_status_block; 2928 word1 = status->word1 >> 16; /* Get the useful bits */ 2929 2930 /* Check the PSR and wrap bits do not match */ 2931 if ((word1 & 0x1FFF) == (rx_local->local_psr_full & 0x1FFF)) 2932 /* Looks like this ring is not updated yet */ 2933 return NULL; 2934 2935 /* The packet status ring indicates that data is available. */ 2936 psr = (struct pkt_stat_desc *) (rx_local->ps_ring_virtaddr) + 2937 (rx_local->local_psr_full & 0xFFF); 2938 2939 /* Grab any information that is required once the PSR is 2940 * advanced, since we can no longer rely on the memory being 2941 * accurate 2942 */ 2943 len = psr->word1 & 0xFFFF; 2944 ring_index = (psr->word1 >> 26) & 0x03; 2945 buff_index = (psr->word1 >> 16) & 0x3FF; 2946 word0 = psr->word0; 2947 2948 /* Indicate that we have used this PSR entry. */ 2949 /* FIXME wrap 12 */ 2950 add_12bit(&rx_local->local_psr_full, 1); 2951 if ( 2952 (rx_local->local_psr_full & 0xFFF) > rx_local->psr_num_entries - 1) { 2953 /* Clear psr full and toggle the wrap bit */ 2954 rx_local->local_psr_full &= ~0xFFF; 2955 rx_local->local_psr_full ^= 0x1000; 2956 } 2957 2958 writel(rx_local->local_psr_full, 2959 &adapter->regs->rxdma.psr_full_offset); 2960 2961#ifndef USE_FBR0 2962 if (ring_index != 1) 2963 return NULL; 2964#endif 2965 2966#ifdef USE_FBR0 2967 if (ring_index > 1 || 2968 (ring_index == 0 && 2969 buff_index > rx_local->fbr[1]->num_entries - 1) || 2970 (ring_index == 1 && 2971 buff_index > rx_local->fbr[0]->num_entries - 1)) { 2972#else 2973 if (ring_index != 1 || buff_index > rx_local->fbr[0]->num_entries - 1) { 2974#endif 2975 /* Illegal buffer or ring index cannot be used by S/W*/ 2976 dev_err(&adapter->pdev->dev, 2977 "NICRxPkts PSR Entry %d indicates " 2978 "length of %d and/or bad bi(%d)\n", 2979 rx_local->local_psr_full & 0xFFF, 2980 len, buff_index); 2981 return NULL; 2982 } 2983 2984 /* Get and fill the RFD. */ 2985 spin_lock_irqsave(&adapter->rcv_lock, flags); 2986 2987 rfd = NULL; 2988 element = rx_local->recv_list.next; 2989 rfd = (struct rfd *) list_entry(element, struct rfd, list_node); 2990 2991 if (rfd == NULL) { 2992 spin_unlock_irqrestore(&adapter->rcv_lock, flags); 2993 return NULL; 2994 } 2995 2996 list_del(&rfd->list_node); 2997 rx_local->num_ready_recv--; 2998 2999 spin_unlock_irqrestore(&adapter->rcv_lock, flags); 3000 3001 rfd->bufferindex = buff_index; 3002 rfd->ringindex = ring_index; 3003 3004 /* In V1 silicon, there is a bug which screws up filtering of 3005 * runt packets. Therefore runt packet filtering is disabled 3006 * in the MAC and the packets are dropped here. They are 3007 * also counted here. 3008 */ 3009 if (len < (NIC_MIN_PACKET_SIZE + 4)) { 3010 adapter->stats.rx_other_errs++; 3011 len = 0; 3012 } 3013 3014 if (len) { 3015 /* Determine if this is a multicast packet coming in */ 3016 if ((word0 & ALCATEL_MULTICAST_PKT) && 3017 !(word0 & ALCATEL_BROADCAST_PKT)) { 3018 /* Promiscuous mode and Multicast mode are 3019 * not mutually exclusive as was first 3020 * thought. I guess Promiscuous is just 3021 * considered a super-set of the other 3022 * filters. Generally filter is 0x2b when in 3023 * promiscuous mode. 3024 */ 3025 if ((adapter->packet_filter & 3026 ET131X_PACKET_TYPE_MULTICAST) 3027 && !(adapter->packet_filter & 3028 ET131X_PACKET_TYPE_PROMISCUOUS) 3029 && !(adapter->packet_filter & 3030 ET131X_PACKET_TYPE_ALL_MULTICAST)) { 3031 /* 3032 * Note - ring_index for fbr[] array is reversed 3033 * 1 for FBR0 etc 3034 */ 3035 buf = rx_local->fbr[(ring_index == 0 ? 1 : 0)]-> 3036 virt[buff_index]; 3037 3038 /* Loop through our list to see if the 3039 * destination address of this packet 3040 * matches one in our list. 3041 */ 3042 for (i = 0; i < adapter->multicast_addr_count; 3043 i++) { 3044 if (buf[0] == 3045 adapter->multicast_list[i][0] 3046 && buf[1] == 3047 adapter->multicast_list[i][1] 3048 && buf[2] == 3049 adapter->multicast_list[i][2] 3050 && buf[3] == 3051 adapter->multicast_list[i][3] 3052 && buf[4] == 3053 adapter->multicast_list[i][4] 3054 && buf[5] == 3055 adapter->multicast_list[i][5]) { 3056 break; 3057 } 3058 } 3059 3060 /* If our index is equal to the number 3061 * of Multicast address we have, then 3062 * this means we did not find this 3063 * packet's matching address in our 3064 * list. Set the len to zero, 3065 * so we free our RFD when we return 3066 * from this function. 3067 */ 3068 if (i == adapter->multicast_addr_count) 3069 len = 0; 3070 } 3071 3072 if (len > 0) 3073 adapter->stats.multicast_pkts_rcvd++; 3074 } else if (word0 & ALCATEL_BROADCAST_PKT) 3075 adapter->stats.broadcast_pkts_rcvd++; 3076 else 3077 /* Not sure what this counter measures in 3078 * promiscuous mode. Perhaps we should check 3079 * the MAC address to see if it is directed 3080 * to us in promiscuous mode. 3081 */ 3082 adapter->stats.unicast_pkts_rcvd++; 3083 } 3084 3085 if (len > 0) { 3086 struct sk_buff *skb = NULL; 3087 3088 /*rfd->len = len - 4; */ 3089 rfd->len = len; 3090 3091 skb = dev_alloc_skb(rfd->len + 2); 3092 if (!skb) { 3093 dev_err(&adapter->pdev->dev, 3094 "Couldn't alloc an SKB for Rx\n"); 3095 return NULL; 3096 } 3097 3098 adapter->net_stats.rx_bytes += rfd->len; 3099 3100 /* 3101 * Note - ring_index for fbr[] array is reversed, 3102 * 1 for FBR0 etc 3103 */ 3104 memcpy(skb_put(skb, rfd->len), 3105 rx_local->fbr[(ring_index == 0 ? 1 : 0)]->virt[buff_index], 3106 rfd->len); 3107 3108 skb->dev = adapter->netdev; 3109 skb->protocol = eth_type_trans(skb, adapter->netdev); 3110 skb->ip_summed = CHECKSUM_NONE; 3111 3112 netif_rx_ni(skb); 3113 } else { 3114 rfd->len = 0; 3115 } 3116 3117 nic_return_rfd(adapter, rfd); 3118 return rfd; 3119} 3120 3121/** 3122 * et131x_handle_recv_interrupt - Interrupt handler for receive processing 3123 * @adapter: pointer to our adapter 3124 * 3125 * Assumption, Rcv spinlock has been acquired. 3126 */ 3127static void et131x_handle_recv_interrupt(struct et131x_adapter *adapter) 3128{ 3129 struct rfd *rfd = NULL; 3130 u32 count = 0; 3131 bool done = true; 3132 3133 /* Process up to available RFD's */ 3134 while (count < NUM_PACKETS_HANDLED) { 3135 if (list_empty(&adapter->rx_ring.recv_list)) { 3136 WARN_ON(adapter->rx_ring.num_ready_recv != 0); 3137 done = false; 3138 break; 3139 } 3140 3141 rfd = nic_rx_pkts(adapter); 3142 3143 if (rfd == NULL) 3144 break; 3145 3146 /* Do not receive any packets until a filter has been set. 3147 * Do not receive any packets until we have link. 3148 * If length is zero, return the RFD in order to advance the 3149 * Free buffer ring. 3150 */ 3151 if (!adapter->packet_filter || 3152 !netif_carrier_ok(adapter->netdev) || 3153 rfd->len == 0) 3154 continue; 3155 3156 /* Increment the number of packets we received */ 3157 adapter->net_stats.rx_packets++; 3158 3159 /* Set the status on the packet, either resources or success */ 3160 if (adapter->rx_ring.num_ready_recv < RFD_LOW_WATER_MARK) { 3161 dev_warn(&adapter->pdev->dev, 3162 "RFD's are running out\n"); 3163 } 3164 count++; 3165 } 3166 3167 if (count == NUM_PACKETS_HANDLED || !done) { 3168 adapter->rx_ring.unfinished_receives = true; 3169 writel(PARM_TX_TIME_INT_DEF * NANO_IN_A_MICRO, 3170 &adapter->regs->global.watchdog_timer); 3171 } else 3172 /* Watchdog timer will disable itself if appropriate. */ 3173 adapter->rx_ring.unfinished_receives = false; 3174} 3175 3176/** 3177 * et131x_tx_dma_memory_alloc 3178 * @adapter: pointer to our private adapter structure 3179 * 3180 * Returns 0 on success and errno on failure (as defined in errno.h). 3181 * 3182 * Allocates memory that will be visible both to the device and to the CPU. 3183 * The OS will pass us packets, pointers to which we will insert in the Tx 3184 * Descriptor queue. The device will read this queue to find the packets in 3185 * memory. The device will update the "status" in memory each time it xmits a 3186 * packet. 3187 */ 3188static int et131x_tx_dma_memory_alloc(struct et131x_adapter *adapter) 3189{ 3190 int desc_size = 0; 3191 struct tx_ring *tx_ring = &adapter->tx_ring; 3192 3193 /* Allocate memory for the TCB's (Transmit Control Block) */ 3194 adapter->tx_ring.tcb_ring = 3195 kcalloc(NUM_TCB, sizeof(struct tcb), GFP_ATOMIC | GFP_DMA); 3196 if (!adapter->tx_ring.tcb_ring) { 3197 dev_err(&adapter->pdev->dev, "Cannot alloc memory for TCBs\n"); 3198 return -ENOMEM; 3199 } 3200 3201 /* Allocate enough memory for the Tx descriptor ring, and allocate 3202 * some extra so that the ring can be aligned on a 4k boundary. 3203 */ 3204 desc_size = (sizeof(struct tx_desc) * NUM_DESC_PER_RING_TX) + 4096 - 1; 3205 tx_ring->tx_desc_ring = 3206 (struct tx_desc *) dma_alloc_coherent(&adapter->pdev->dev, 3207 desc_size, 3208 &tx_ring->tx_desc_ring_pa, 3209 GFP_KERNEL); 3210 if (!adapter->tx_ring.tx_desc_ring) { 3211 dev_err(&adapter->pdev->dev, 3212 "Cannot alloc memory for Tx Ring\n"); 3213 return -ENOMEM; 3214 } 3215 3216 /* Save physical address 3217 * 3218 * NOTE: dma_alloc_coherent(), used above to alloc DMA regions, 3219 * ALWAYS returns SAC (32-bit) addresses. If DAC (64-bit) addresses 3220 * are ever returned, make sure the high part is retrieved here before 3221 * storing the adjusted address. 3222 */ 3223 /* Allocate memory for the Tx status block */ 3224 tx_ring->tx_status = dma_alloc_coherent(&adapter->pdev->dev, 3225 sizeof(u32), 3226 &tx_ring->tx_status_pa, 3227 GFP_KERNEL); 3228 if (!adapter->tx_ring.tx_status_pa) { 3229 dev_err(&adapter->pdev->dev, 3230 "Cannot alloc memory for Tx status block\n"); 3231 return -ENOMEM; 3232 } 3233 return 0; 3234} 3235 3236/** 3237 * et131x_tx_dma_memory_free - Free all memory allocated within this module 3238 * @adapter: pointer to our private adapter structure 3239 * 3240 * Returns 0 on success and errno on failure (as defined in errno.h). 3241 */ 3242static void et131x_tx_dma_memory_free(struct et131x_adapter *adapter) 3243{ 3244 int desc_size = 0; 3245 3246 if (adapter->tx_ring.tx_desc_ring) { 3247 /* Free memory relating to Tx rings here */ 3248 desc_size = (sizeof(struct tx_desc) * NUM_DESC_PER_RING_TX) 3249 + 4096 - 1; 3250 dma_free_coherent(&adapter->pdev->dev, 3251 desc_size, 3252 adapter->tx_ring.tx_desc_ring, 3253 adapter->tx_ring.tx_desc_ring_pa); 3254 adapter->tx_ring.tx_desc_ring = NULL; 3255 } 3256 3257 /* Free memory for the Tx status block */ 3258 if (adapter->tx_ring.tx_status) { 3259 dma_free_coherent(&adapter->pdev->dev, 3260 sizeof(u32), 3261 adapter->tx_ring.tx_status, 3262 adapter->tx_ring.tx_status_pa); 3263 3264 adapter->tx_ring.tx_status = NULL; 3265 } 3266 /* Free the memory for the tcb structures */ 3267 kfree(adapter->tx_ring.tcb_ring); 3268} 3269 3270/** 3271 * nic_send_packet - NIC specific send handler for version B silicon. 3272 * @adapter: pointer to our adapter 3273 * @tcb: pointer to struct tcb 3274 * 3275 * Returns 0 or errno. 3276 */ 3277static int nic_send_packet(struct et131x_adapter *adapter, struct tcb *tcb) 3278{ 3279 u32 i; 3280 struct tx_desc desc[24]; /* 24 x 16 byte */ 3281 u32 frag = 0; 3282 u32 thiscopy, remainder; 3283 struct sk_buff *skb = tcb->skb; 3284 u32 nr_frags = skb_shinfo(skb)->nr_frags + 1; 3285 struct skb_frag_struct *frags = &skb_shinfo(skb)->frags[0]; 3286 unsigned long flags; 3287 struct phy_device *phydev = adapter->phydev; 3288 3289 /* Part of the optimizations of this send routine restrict us to 3290 * sending 24 fragments at a pass. In practice we should never see 3291 * more than 5 fragments. 3292 * 3293 * NOTE: The older version of this function (below) can handle any 3294 * number of fragments. If needed, we can call this function, 3295 * although it is less efficient. 3296 */ 3297 if (nr_frags > 23) 3298 return -EIO; 3299 3300 memset(desc, 0, sizeof(struct tx_desc) * (nr_frags + 1)); 3301 3302 for (i = 0; i < nr_frags; i++) { 3303 /* If there is something in this element, lets get a 3304 * descriptor from the ring and get the necessary data 3305 */ 3306 if (i == 0) { 3307 /* If the fragments are smaller than a standard MTU, 3308 * then map them to a single descriptor in the Tx 3309 * Desc ring. However, if they're larger, as is 3310 * possible with support for jumbo packets, then 3311 * split them each across 2 descriptors. 3312 * 3313 * This will work until we determine why the hardware 3314 * doesn't seem to like large fragments. 3315 */ 3316 if ((skb->len - skb->data_len) <= 1514) { 3317 desc[frag].addr_hi = 0; 3318 /* Low 16bits are length, high is vlan and 3319 unused currently so zero */ 3320 desc[frag].len_vlan = 3321 skb->len - skb->data_len; 3322 3323 /* NOTE: Here, the dma_addr_t returned from 3324 * dma_map_single() is implicitly cast as a 3325 * u32. Although dma_addr_t can be 3326 * 64-bit, the address returned by 3327 * dma_map_single() is always 32-bit 3328 * addressable (as defined by the pci/dma 3329 * subsystem) 3330 */ 3331 desc[frag++].addr_lo = 3332 dma_map_single(&adapter->pdev->dev, 3333 skb->data, 3334 skb->len - 3335 skb->data_len, 3336 DMA_TO_DEVICE); 3337 } else { 3338 desc[frag].addr_hi = 0; 3339 desc[frag].len_vlan = 3340 (skb->len - skb->data_len) / 2; 3341 3342 /* NOTE: Here, the dma_addr_t returned from 3343 * dma_map_single() is implicitly cast as a 3344 * u32. Although dma_addr_t can be 3345 * 64-bit, the address returned by 3346 * dma_map_single() is always 32-bit 3347 * addressable (as defined by the pci/dma 3348 * subsystem) 3349 */ 3350 desc[frag++].addr_lo = 3351 dma_map_single(&adapter->pdev->dev, 3352 skb->data, 3353 ((skb->len - 3354 skb->data_len) / 2), 3355 DMA_TO_DEVICE); 3356 desc[frag].addr_hi = 0; 3357 3358 desc[frag].len_vlan = 3359 (skb->len - skb->data_len) / 2; 3360 3361 /* NOTE: Here, the dma_addr_t returned from 3362 * dma_map_single() is implicitly cast as a 3363 * u32. Although dma_addr_t can be 3364 * 64-bit, the address returned by 3365 * dma_map_single() is always 32-bit 3366 * addressable (as defined by the pci/dma 3367 * subsystem) 3368 */ 3369 desc[frag++].addr_lo = 3370 dma_map_single(&adapter->pdev->dev, 3371 skb->data + 3372 ((skb->len - 3373 skb->data_len) / 2), 3374 ((skb->len - 3375 skb->data_len) / 2), 3376 DMA_TO_DEVICE); 3377 } 3378 } else { 3379 desc[frag].addr_hi = 0; 3380 desc[frag].len_vlan = 3381 frags[i - 1].size; 3382 3383 /* NOTE: Here, the dma_addr_t returned from 3384 * dma_map_page() is implicitly cast as a u32. 3385 * Although dma_addr_t can be 64-bit, the address 3386 * returned by dma_map_page() is always 32-bit 3387 * addressable (as defined by the pci/dma subsystem) 3388 */ 3389 desc[frag++].addr_lo = skb_frag_dma_map( 3390 &adapter->pdev->dev, 3391 &frags[i - 1], 3392 0, 3393 frags[i - 1].size, 3394 DMA_TO_DEVICE); 3395 } 3396 } 3397 3398 if (phydev && phydev->speed == SPEED_1000) { 3399 if (++adapter->tx_ring.since_irq == PARM_TX_NUM_BUFS_DEF) { 3400 /* Last element & Interrupt flag */ 3401 desc[frag - 1].flags = 0x5; 3402 adapter->tx_ring.since_irq = 0; 3403 } else { /* Last element */ 3404 desc[frag - 1].flags = 0x1; 3405 } 3406 } else 3407 desc[frag - 1].flags = 0x5; 3408 3409 desc[0].flags |= 2; /* First element flag */ 3410 3411 tcb->index_start = adapter->tx_ring.send_idx; 3412 tcb->stale = 0; 3413 3414 spin_lock_irqsave(&adapter->send_hw_lock, flags); 3415 3416 thiscopy = NUM_DESC_PER_RING_TX - 3417 INDEX10(adapter->tx_ring.send_idx); 3418 3419 if (thiscopy >= frag) { 3420 remainder = 0; 3421 thiscopy = frag; 3422 } else { 3423 remainder = frag - thiscopy; 3424 } 3425 3426 memcpy(adapter->tx_ring.tx_desc_ring + 3427 INDEX10(adapter->tx_ring.send_idx), desc, 3428 sizeof(struct tx_desc) * thiscopy); 3429 3430 add_10bit(&adapter->tx_ring.send_idx, thiscopy); 3431 3432 if (INDEX10(adapter->tx_ring.send_idx) == 0 || 3433 INDEX10(adapter->tx_ring.send_idx) == NUM_DESC_PER_RING_TX) { 3434 adapter->tx_ring.send_idx &= ~ET_DMA10_MASK; 3435 adapter->tx_ring.send_idx ^= ET_DMA10_WRAP; 3436 } 3437 3438 if (remainder) { 3439 memcpy(adapter->tx_ring.tx_desc_ring, 3440 desc + thiscopy, 3441 sizeof(struct tx_desc) * remainder); 3442 3443 add_10bit(&adapter->tx_ring.send_idx, remainder); 3444 } 3445 3446 if (INDEX10(adapter->tx_ring.send_idx) == 0) { 3447 if (adapter->tx_ring.send_idx) 3448 tcb->index = NUM_DESC_PER_RING_TX - 1; 3449 else 3450 tcb->index = ET_DMA10_WRAP|(NUM_DESC_PER_RING_TX - 1); 3451 } else 3452 tcb->index = adapter->tx_ring.send_idx - 1; 3453 3454 spin_lock(&adapter->tcb_send_qlock); 3455 3456 if (adapter->tx_ring.send_tail) 3457 adapter->tx_ring.send_tail->next = tcb; 3458 else 3459 adapter->tx_ring.send_head = tcb; 3460 3461 adapter->tx_ring.send_tail = tcb; 3462 3463 WARN_ON(tcb->next != NULL); 3464 3465 adapter->tx_ring.used++; 3466 3467 spin_unlock(&adapter->tcb_send_qlock); 3468 3469 /* Write the new write pointer back to the device. */ 3470 writel(adapter->tx_ring.send_idx, 3471 &adapter->regs->txdma.service_request); 3472 3473 /* For Gig only, we use Tx Interrupt coalescing. Enable the software 3474 * timer to wake us up if this packet isn't followed by N more. 3475 */ 3476 if (phydev && phydev->speed == SPEED_1000) { 3477 writel(PARM_TX_TIME_INT_DEF * NANO_IN_A_MICRO, 3478 &adapter->regs->global.watchdog_timer); 3479 } 3480 spin_unlock_irqrestore(&adapter->send_hw_lock, flags); 3481 3482 return 0; 3483} 3484 3485/** 3486 * send_packet - Do the work to send a packet 3487 * @skb: the packet(s) to send 3488 * @adapter: a pointer to the device's private adapter structure 3489 * 3490 * Return 0 in almost all cases; non-zero value in extreme hard failure only. 3491 * 3492 * Assumption: Send spinlock has been acquired 3493 */ 3494static int send_packet(struct sk_buff *skb, struct et131x_adapter *adapter) 3495{ 3496 int status; 3497 struct tcb *tcb = NULL; 3498 u16 *shbufva; 3499 unsigned long flags; 3500 3501 /* All packets must have at least a MAC address and a protocol type */ 3502 if (skb->len < ETH_HLEN) 3503 return -EIO; 3504 3505 /* Get a TCB for this packet */ 3506 spin_lock_irqsave(&adapter->tcb_ready_qlock, flags); 3507 3508 tcb = adapter->tx_ring.tcb_qhead; 3509 3510 if (tcb == NULL) { 3511 spin_unlock_irqrestore(&adapter->tcb_ready_qlock, flags); 3512 return -ENOMEM; 3513 } 3514 3515 adapter->tx_ring.tcb_qhead = tcb->next; 3516 3517 if (adapter->tx_ring.tcb_qhead == NULL) 3518 adapter->tx_ring.tcb_qtail = NULL; 3519 3520 spin_unlock_irqrestore(&adapter->tcb_ready_qlock, flags); 3521 3522 tcb->skb = skb; 3523 3524 if (skb->data != NULL && skb->len - skb->data_len >= 6) { 3525 shbufva = (u16 *) skb->data; 3526 3527 if ((shbufva[0] == 0xffff) && 3528 (shbufva[1] == 0xffff) && (shbufva[2] == 0xffff)) { 3529 tcb->flags |= fMP_DEST_BROAD; 3530 } else if ((shbufva[0] & 0x3) == 0x0001) { 3531 tcb->flags |= fMP_DEST_MULTI; 3532 } 3533 } 3534 3535 tcb->next = NULL; 3536 3537 /* Call the NIC specific send handler. */ 3538 status = nic_send_packet(adapter, tcb); 3539 3540 if (status != 0) { 3541 spin_lock_irqsave(&adapter->tcb_ready_qlock, flags); 3542 3543 if (adapter->tx_ring.tcb_qtail) 3544 adapter->tx_ring.tcb_qtail->next = tcb; 3545 else 3546 /* Apparently ready Q is empty. */ 3547 adapter->tx_ring.tcb_qhead = tcb; 3548 3549 adapter->tx_ring.tcb_qtail = tcb; 3550 spin_unlock_irqrestore(&adapter->tcb_ready_qlock, flags); 3551 return status; 3552 } 3553 WARN_ON(adapter->tx_ring.used > NUM_TCB); 3554 return 0; 3555} 3556 3557/** 3558 * et131x_send_packets - This function is called by the OS to send packets 3559 * @skb: the packet(s) to send 3560 * @netdev:device on which to TX the above packet(s) 3561 * 3562 * Return 0 in almost all cases; non-zero value in extreme hard failure only 3563 */ 3564static int et131x_send_packets(struct sk_buff *skb, struct net_device *netdev) 3565{ 3566 int status = 0; 3567 struct et131x_adapter *adapter = netdev_priv(netdev); 3568 3569 /* Send these packets 3570 * 3571 * NOTE: The Linux Tx entry point is only given one packet at a time 3572 * to Tx, so the PacketCount and it's array used makes no sense here 3573 */ 3574 3575 /* TCB is not available */ 3576 if (adapter->tx_ring.used >= NUM_TCB) { 3577 /* NOTE: If there's an error on send, no need to queue the 3578 * packet under Linux; if we just send an error up to the 3579 * netif layer, it will resend the skb to us. 3580 */ 3581 status = -ENOMEM; 3582 } else { 3583 /* We need to see if the link is up; if it's not, make the 3584 * netif layer think we're good and drop the packet 3585 */ 3586 if ((adapter->flags & fMP_ADAPTER_FAIL_SEND_MASK) || 3587 !netif_carrier_ok(netdev)) { 3588 dev_kfree_skb_any(skb); 3589 skb = NULL; 3590 3591 adapter->net_stats.tx_dropped++; 3592 } else { 3593 status = send_packet(skb, adapter); 3594 if (status != 0 && status != -ENOMEM) { 3595 /* On any other error, make netif think we're 3596 * OK and drop the packet 3597 */ 3598 dev_kfree_skb_any(skb); 3599 skb = NULL; 3600 adapter->net_stats.tx_dropped++; 3601 } 3602 } 3603 } 3604 return status; 3605} 3606 3607/** 3608 * free_send_packet - Recycle a struct tcb 3609 * @adapter: pointer to our adapter 3610 * @tcb: pointer to struct tcb 3611 * 3612 * Complete the packet if necessary 3613 * Assumption - Send spinlock has been acquired 3614 */ 3615static inline void free_send_packet(struct et131x_adapter *adapter, 3616 struct tcb *tcb) 3617{ 3618 unsigned long flags; 3619 struct tx_desc *desc = NULL; 3620 struct net_device_stats *stats = &adapter->net_stats; 3621 3622 if (tcb->flags & fMP_DEST_BROAD) 3623 atomic_inc(&adapter->stats.broadcast_pkts_xmtd); 3624 else if (tcb->flags & fMP_DEST_MULTI) 3625 atomic_inc(&adapter->stats.multicast_pkts_xmtd); 3626 else 3627 atomic_inc(&adapter->stats.unicast_pkts_xmtd); 3628 3629 if (tcb->skb) { 3630 stats->tx_bytes += tcb->skb->len; 3631 3632 /* Iterate through the TX descriptors on the ring 3633 * corresponding to this packet and umap the fragments 3634 * they point to 3635 */ 3636 do { 3637 desc = (struct tx_desc *) 3638 (adapter->tx_ring.tx_desc_ring + 3639 INDEX10(tcb->index_start)); 3640 3641 dma_unmap_single(&adapter->pdev->dev, 3642 desc->addr_lo, 3643 desc->len_vlan, DMA_TO_DEVICE); 3644 3645 add_10bit(&tcb->index_start, 1); 3646 if (INDEX10(tcb->index_start) >= 3647 NUM_DESC_PER_RING_TX) { 3648 tcb->index_start &= ~ET_DMA10_MASK; 3649 tcb->index_start ^= ET_DMA10_WRAP; 3650 } 3651 } while (desc != (adapter->tx_ring.tx_desc_ring + 3652 INDEX10(tcb->index))); 3653 3654 dev_kfree_skb_any(tcb->skb); 3655 } 3656 3657 memset(tcb, 0, sizeof(struct tcb)); 3658 3659 /* Add the TCB to the Ready Q */ 3660 spin_lock_irqsave(&adapter->tcb_ready_qlock, flags); 3661 3662 adapter->net_stats.tx_packets++; 3663 3664 if (adapter->tx_ring.tcb_qtail) 3665 adapter->tx_ring.tcb_qtail->next = tcb; 3666 else 3667 /* Apparently ready Q is empty. */ 3668 adapter->tx_ring.tcb_qhead = tcb; 3669 3670 adapter->tx_ring.tcb_qtail = tcb; 3671 3672 spin_unlock_irqrestore(&adapter->tcb_ready_qlock, flags); 3673 WARN_ON(adapter->tx_ring.used < 0); 3674} 3675 3676/** 3677 * et131x_free_busy_send_packets - Free and complete the stopped active sends 3678 * @adapter: pointer to our adapter 3679 * 3680 * Assumption - Send spinlock has been acquired 3681 */ 3682static void et131x_free_busy_send_packets(struct et131x_adapter *adapter) 3683{ 3684 struct tcb *tcb; 3685 unsigned long flags; 3686 u32 freed = 0; 3687 3688 /* Any packets being sent? Check the first TCB on the send list */ 3689 spin_lock_irqsave(&adapter->tcb_send_qlock, flags); 3690 3691 tcb = adapter->tx_ring.send_head; 3692 3693 while (tcb != NULL && freed < NUM_TCB) { 3694 struct tcb *next = tcb->next; 3695 3696 adapter->tx_ring.send_head = next; 3697 3698 if (next == NULL) 3699 adapter->tx_ring.send_tail = NULL; 3700 3701 adapter->tx_ring.used--; 3702 3703 spin_unlock_irqrestore(&adapter->tcb_send_qlock, flags); 3704 3705 freed++; 3706 free_send_packet(adapter, tcb); 3707 3708 spin_lock_irqsave(&adapter->tcb_send_qlock, flags); 3709 3710 tcb = adapter->tx_ring.send_head; 3711 } 3712 3713 WARN_ON(freed == NUM_TCB); 3714 3715 spin_unlock_irqrestore(&adapter->tcb_send_qlock, flags); 3716 3717 adapter->tx_ring.used = 0; 3718} 3719 3720/** 3721 * et131x_handle_send_interrupt - Interrupt handler for sending processing 3722 * @adapter: pointer to our adapter 3723 * 3724 * Re-claim the send resources, complete sends and get more to send from 3725 * the send wait queue. 3726 * 3727 * Assumption - Send spinlock has been acquired 3728 */ 3729static void et131x_handle_send_interrupt(struct et131x_adapter *adapter) 3730{ 3731 unsigned long flags; 3732 u32 serviced; 3733 struct tcb *tcb; 3734 u32 index; 3735 3736 serviced = readl(&adapter->regs->txdma.new_service_complete); 3737 index = INDEX10(serviced); 3738 3739 /* Has the ring wrapped? Process any descriptors that do not have 3740 * the same "wrap" indicator as the current completion indicator 3741 */ 3742 spin_lock_irqsave(&adapter->tcb_send_qlock, flags); 3743 3744 tcb = adapter->tx_ring.send_head; 3745 3746 while (tcb && 3747 ((serviced ^ tcb->index) & ET_DMA10_WRAP) && 3748 index < INDEX10(tcb->index)) { 3749 adapter->tx_ring.used--; 3750 adapter->tx_ring.send_head = tcb->next; 3751 if (tcb->next == NULL) 3752 adapter->tx_ring.send_tail = NULL; 3753 3754 spin_unlock_irqrestore(&adapter->tcb_send_qlock, flags); 3755 free_send_packet(adapter, tcb); 3756 spin_lock_irqsave(&adapter->tcb_send_qlock, flags); 3757 3758 /* Goto the next packet */ 3759 tcb = adapter->tx_ring.send_head; 3760 } 3761 while (tcb && 3762 !((serviced ^ tcb->index) & ET_DMA10_WRAP) 3763 && index > (tcb->index & ET_DMA10_MASK)) { 3764 adapter->tx_ring.used--; 3765 adapter->tx_ring.send_head = tcb->next; 3766 if (tcb->next == NULL) 3767 adapter->tx_ring.send_tail = NULL; 3768 3769 spin_unlock_irqrestore(&adapter->tcb_send_qlock, flags); 3770 free_send_packet(adapter, tcb); 3771 spin_lock_irqsave(&adapter->tcb_send_qlock, flags); 3772 3773 /* Goto the next packet */ 3774 tcb = adapter->tx_ring.send_head; 3775 } 3776 3777 /* Wake up the queue when we hit a low-water mark */ 3778 if (adapter->tx_ring.used <= NUM_TCB / 3) 3779 netif_wake_queue(adapter->netdev); 3780 3781 spin_unlock_irqrestore(&adapter->tcb_send_qlock, flags); 3782} 3783 3784static int et131x_get_settings(struct net_device *netdev, 3785 struct ethtool_cmd *cmd) 3786{ 3787 struct et131x_adapter *adapter = netdev_priv(netdev); 3788 3789 return phy_ethtool_gset(adapter->phydev, cmd); 3790} 3791 3792static int et131x_set_settings(struct net_device *netdev, 3793 struct ethtool_cmd *cmd) 3794{ 3795 struct et131x_adapter *adapter = netdev_priv(netdev); 3796 3797 return phy_ethtool_sset(adapter->phydev, cmd); 3798} 3799 3800static int et131x_get_regs_len(struct net_device *netdev) 3801{ 3802#define ET131X_REGS_LEN 256 3803 return ET131X_REGS_LEN * sizeof(u32); 3804} 3805 3806static void et131x_get_regs(struct net_device *netdev, 3807 struct ethtool_regs *regs, void *regs_data) 3808{ 3809 struct et131x_adapter *adapter = netdev_priv(netdev); 3810 struct address_map __iomem *aregs = adapter->regs; 3811 u32 *regs_buff = regs_data; 3812 u32 num = 0; 3813 3814 memset(regs_data, 0, et131x_get_regs_len(netdev)); 3815 3816 regs->version = (1 << 24) | (adapter->pdev->revision << 16) | 3817 adapter->pdev->device; 3818 3819 /* PHY regs */ 3820 et131x_mii_read(adapter, MII_BMCR, (u16 *)&regs_buff[num++]); 3821 et131x_mii_read(adapter, MII_BMSR, (u16 *)&regs_buff[num++]); 3822 et131x_mii_read(adapter, MII_PHYSID1, (u16 *)&regs_buff[num++]); 3823 et131x_mii_read(adapter, MII_PHYSID2, (u16 *)&regs_buff[num++]); 3824 et131x_mii_read(adapter, MII_ADVERTISE, (u16 *)&regs_buff[num++]); 3825 et131x_mii_read(adapter, MII_LPA, (u16 *)&regs_buff[num++]); 3826 et131x_mii_read(adapter, MII_EXPANSION, (u16 *)&regs_buff[num++]); 3827 /* Autoneg next page transmit reg */ 3828 et131x_mii_read(adapter, 0x07, (u16 *)&regs_buff[num++]); 3829 /* Link partner next page reg */ 3830 et131x_mii_read(adapter, 0x08, (u16 *)&regs_buff[num++]); 3831 et131x_mii_read(adapter, MII_CTRL1000, (u16 *)&regs_buff[num++]); 3832 et131x_mii_read(adapter, MII_STAT1000, (u16 *)&regs_buff[num++]); 3833 et131x_mii_read(adapter, MII_ESTATUS, (u16 *)&regs_buff[num++]); 3834 et131x_mii_read(adapter, PHY_INDEX_REG, (u16 *)&regs_buff[num++]); 3835 et131x_mii_read(adapter, PHY_DATA_REG, (u16 *)&regs_buff[num++]); 3836 et131x_mii_read(adapter, PHY_MPHY_CONTROL_REG, 3837 (u16 *)&regs_buff[num++]); 3838 et131x_mii_read(adapter, PHY_LOOPBACK_CONTROL, 3839 (u16 *)&regs_buff[num++]); 3840 et131x_mii_read(adapter, PHY_LOOPBACK_CONTROL+1, 3841 (u16 *)&regs_buff[num++]); 3842 et131x_mii_read(adapter, PHY_REGISTER_MGMT_CONTROL, 3843 (u16 *)&regs_buff[num++]); 3844 et131x_mii_read(adapter, PHY_CONFIG, (u16 *)&regs_buff[num++]); 3845 et131x_mii_read(adapter, PHY_PHY_CONTROL, (u16 *)&regs_buff[num++]); 3846 et131x_mii_read(adapter, PHY_INTERRUPT_MASK, (u16 *)&regs_buff[num++]); 3847 et131x_mii_read(adapter, PHY_INTERRUPT_STATUS, 3848 (u16 *)&regs_buff[num++]); 3849 et131x_mii_read(adapter, PHY_PHY_STATUS, (u16 *)&regs_buff[num++]); 3850 et131x_mii_read(adapter, PHY_LED_1, (u16 *)&regs_buff[num++]); 3851 et131x_mii_read(adapter, PHY_LED_2, (u16 *)&regs_buff[num++]); 3852 3853 /* Global regs */ 3854 regs_buff[num++] = readl(&aregs->global.txq_start_addr); 3855 regs_buff[num++] = readl(&aregs->global.txq_end_addr); 3856 regs_buff[num++] = readl(&aregs->global.rxq_start_addr); 3857 regs_buff[num++] = readl(&aregs->global.rxq_end_addr); 3858 regs_buff[num++] = readl(&aregs->global.pm_csr); 3859 regs_buff[num++] = adapter->stats.interrupt_status; 3860 regs_buff[num++] = readl(&aregs->global.int_mask); 3861 regs_buff[num++] = readl(&aregs->global.int_alias_clr_en); 3862 regs_buff[num++] = readl(&aregs->global.int_status_alias); 3863 regs_buff[num++] = readl(&aregs->global.sw_reset); 3864 regs_buff[num++] = readl(&aregs->global.slv_timer); 3865 regs_buff[num++] = readl(&aregs->global.msi_config); 3866 regs_buff[num++] = readl(&aregs->global.loopback); 3867 regs_buff[num++] = readl(&aregs->global.watchdog_timer); 3868 3869 /* TXDMA regs */ 3870 regs_buff[num++] = readl(&aregs->txdma.csr); 3871 regs_buff[num++] = readl(&aregs->txdma.pr_base_hi); 3872 regs_buff[num++] = readl(&aregs->txdma.pr_base_lo); 3873 regs_buff[num++] = readl(&aregs->txdma.pr_num_des); 3874 regs_buff[num++] = readl(&aregs->txdma.txq_wr_addr); 3875 regs_buff[num++] = readl(&aregs->txdma.txq_wr_addr_ext); 3876 regs_buff[num++] = readl(&aregs->txdma.txq_rd_addr); 3877 regs_buff[num++] = readl(&aregs->txdma.dma_wb_base_hi); 3878 regs_buff[num++] = readl(&aregs->txdma.dma_wb_base_lo); 3879 regs_buff[num++] = readl(&aregs->txdma.service_request); 3880 regs_buff[num++] = readl(&aregs->txdma.service_complete); 3881 regs_buff[num++] = readl(&aregs->txdma.cache_rd_index); 3882 regs_buff[num++] = readl(&aregs->txdma.cache_wr_index); 3883 regs_buff[num++] = readl(&aregs->txdma.tx_dma_error); 3884 regs_buff[num++] = readl(&aregs->txdma.desc_abort_cnt); 3885 regs_buff[num++] = readl(&aregs->txdma.payload_abort_cnt); 3886 regs_buff[num++] = readl(&aregs->txdma.writeback_abort_cnt); 3887 regs_buff[num++] = readl(&aregs->txdma.desc_timeout_cnt); 3888 regs_buff[num++] = readl(&aregs->txdma.payload_timeout_cnt); 3889 regs_buff[num++] = readl(&aregs->txdma.writeback_timeout_cnt); 3890 regs_buff[num++] = readl(&aregs->txdma.desc_error_cnt); 3891 regs_buff[num++] = readl(&aregs->txdma.payload_error_cnt); 3892 regs_buff[num++] = readl(&aregs->txdma.writeback_error_cnt); 3893 regs_buff[num++] = readl(&aregs->txdma.dropped_tlp_cnt); 3894 regs_buff[num++] = readl(&aregs->txdma.new_service_complete); 3895 regs_buff[num++] = readl(&aregs->txdma.ethernet_packet_cnt); 3896 3897 /* RXDMA regs */ 3898 regs_buff[num++] = readl(&aregs->rxdma.csr); 3899 regs_buff[num++] = readl(&aregs->rxdma.dma_wb_base_hi); 3900 regs_buff[num++] = readl(&aregs->rxdma.dma_wb_base_lo); 3901 regs_buff[num++] = readl(&aregs->rxdma.num_pkt_done); 3902 regs_buff[num++] = readl(&aregs->rxdma.max_pkt_time); 3903 regs_buff[num++] = readl(&aregs->rxdma.rxq_rd_addr); 3904 regs_buff[num++] = readl(&aregs->rxdma.rxq_rd_addr_ext); 3905 regs_buff[num++] = readl(&aregs->rxdma.rxq_wr_addr); 3906 regs_buff[num++] = readl(&aregs->rxdma.psr_base_hi); 3907 regs_buff[num++] = readl(&aregs->rxdma.psr_base_lo); 3908 regs_buff[num++] = readl(&aregs->rxdma.psr_num_des); 3909 regs_buff[num++] = readl(&aregs->rxdma.psr_avail_offset); 3910 regs_buff[num++] = readl(&aregs->rxdma.psr_full_offset); 3911 regs_buff[num++] = readl(&aregs->rxdma.psr_access_index); 3912 regs_buff[num++] = readl(&aregs->rxdma.psr_min_des); 3913 regs_buff[num++] = readl(&aregs->rxdma.fbr0_base_lo); 3914 regs_buff[num++] = readl(&aregs->rxdma.fbr0_base_hi); 3915 regs_buff[num++] = readl(&aregs->rxdma.fbr0_num_des); 3916 regs_buff[num++] = readl(&aregs->rxdma.fbr0_avail_offset); 3917 regs_buff[num++] = readl(&aregs->rxdma.fbr0_full_offset); 3918 regs_buff[num++] = readl(&aregs->rxdma.fbr0_rd_index); 3919 regs_buff[num++] = readl(&aregs->rxdma.fbr0_min_des); 3920 regs_buff[num++] = readl(&aregs->rxdma.fbr1_base_lo); 3921 regs_buff[num++] = readl(&aregs->rxdma.fbr1_base_hi); 3922 regs_buff[num++] = readl(&aregs->rxdma.fbr1_num_des); 3923 regs_buff[num++] = readl(&aregs->rxdma.fbr1_avail_offset); 3924 regs_buff[num++] = readl(&aregs->rxdma.fbr1_full_offset); 3925 regs_buff[num++] = readl(&aregs->rxdma.fbr1_rd_index); 3926 regs_buff[num++] = readl(&aregs->rxdma.fbr1_min_des); 3927} 3928 3929#define ET131X_DRVINFO_LEN 32 /* value from ethtool.h */ 3930static void et131x_get_drvinfo(struct net_device *netdev, 3931 struct ethtool_drvinfo *info) 3932{ 3933 struct et131x_adapter *adapter = netdev_priv(netdev); 3934 3935 strncpy(info->driver, DRIVER_NAME, ET131X_DRVINFO_LEN); 3936 strncpy(info->version, DRIVER_VERSION, ET131X_DRVINFO_LEN); 3937 strncpy(info->bus_info, pci_name(adapter->pdev), ET131X_DRVINFO_LEN); 3938} 3939 3940static struct ethtool_ops et131x_ethtool_ops = { 3941 .get_settings = et131x_get_settings, 3942 .set_settings = et131x_set_settings, 3943 .get_drvinfo = et131x_get_drvinfo, 3944 .get_regs_len = et131x_get_regs_len, 3945 .get_regs = et131x_get_regs, 3946 .get_link = ethtool_op_get_link, 3947}; 3948/** 3949 * et131x_hwaddr_init - set up the MAC Address on the ET1310 3950 * @adapter: pointer to our private adapter structure 3951 */ 3952static void et131x_hwaddr_init(struct et131x_adapter *adapter) 3953{ 3954 /* If have our default mac from init and no mac address from 3955 * EEPROM then we need to generate the last octet and set it on the 3956 * device 3957 */ 3958 if (adapter->rom_addr[0] == 0x00 && 3959 adapter->rom_addr[1] == 0x00 && 3960 adapter->rom_addr[2] == 0x00 && 3961 adapter->rom_addr[3] == 0x00 && 3962 adapter->rom_addr[4] == 0x00 && 3963 adapter->rom_addr[5] == 0x00) { 3964 /* 3965 * We need to randomly generate the last octet so we 3966 * decrease our chances of setting the mac address to 3967 * same as another one of our cards in the system 3968 */ 3969 get_random_bytes(&adapter->addr[5], 1); 3970 /* 3971 * We have the default value in the register we are 3972 * working with so we need to copy the current 3973 * address into the permanent address 3974 */ 3975 memcpy(adapter->rom_addr, 3976 adapter->addr, ETH_ALEN); 3977 } else { 3978 /* We do not have an override address, so set the 3979 * current address to the permanent address and add 3980 * it to the device 3981 */ 3982 memcpy(adapter->addr, 3983 adapter->rom_addr, ETH_ALEN); 3984 } 3985} 3986 3987/** 3988 * et131x_pci_init - initial PCI setup 3989 * @adapter: pointer to our private adapter structure 3990 * @pdev: our PCI device 3991 * 3992 * Perform the initial setup of PCI registers and if possible initialise 3993 * the MAC address. At this point the I/O registers have yet to be mapped 3994 */ 3995static int et131x_pci_init(struct et131x_adapter *adapter, 3996 struct pci_dev *pdev) 3997{ 3998 int cap = pci_pcie_cap(pdev); 3999 u16 max_payload; 4000 u16 ctl; 4001 int i, rc; 4002 4003 rc = et131x_init_eeprom(adapter); 4004 if (rc < 0) 4005 goto out; 4006 4007 if (!cap) { 4008 dev_err(&pdev->dev, "Missing PCIe capabilities\n"); 4009 goto err_out; 4010 } 4011 4012 /* Let's set up the PORT LOGIC Register. First we need to know what 4013 * the max_payload_size is 4014 */ 4015 if (pci_read_config_word(pdev, cap + PCI_EXP_DEVCAP, &max_payload)) { 4016 dev_err(&pdev->dev, 4017 "Could not read PCI config space for Max Payload Size\n"); 4018 goto err_out; 4019 } 4020 4021 /* Program the Ack/Nak latency and replay timers */ 4022 max_payload &= 0x07; 4023 4024 if (max_payload < 2) { 4025 static const u16 acknak[2] = { 0x76, 0xD0 }; 4026 static const u16 replay[2] = { 0x1E0, 0x2ED }; 4027 4028 if (pci_write_config_word(pdev, ET1310_PCI_ACK_NACK, 4029 acknak[max_payload])) { 4030 dev_err(&pdev->dev, 4031 "Could not write PCI config space for ACK/NAK\n"); 4032 goto err_out; 4033 } 4034 if (pci_write_config_word(pdev, ET1310_PCI_REPLAY, 4035 replay[max_payload])) { 4036 dev_err(&pdev->dev, 4037 "Could not write PCI config space for Replay Timer\n"); 4038 goto err_out; 4039 } 4040 } 4041 4042 /* l0s and l1 latency timers. We are using default values. 4043 * Representing 001 for L0s and 010 for L1 4044 */ 4045 if (pci_write_config_byte(pdev, ET1310_PCI_L0L1LATENCY, 0x11)) { 4046 dev_err(&pdev->dev, 4047 "Could not write PCI config space for Latency Timers\n"); 4048 goto err_out; 4049 } 4050 4051 /* Change the max read size to 2k */ 4052 if (pci_read_config_word(pdev, cap + PCI_EXP_DEVCTL, &ctl)) { 4053 dev_err(&pdev->dev, 4054 "Could not read PCI config space for Max read size\n"); 4055 goto err_out; 4056 } 4057 4058 ctl = (ctl & ~PCI_EXP_DEVCTL_READRQ) | (0x04 << 12); 4059 4060 if (pci_write_config_word(pdev, cap + PCI_EXP_DEVCTL, ctl)) { 4061 dev_err(&pdev->dev, 4062 "Could not write PCI config space for Max read size\n"); 4063 goto err_out; 4064 } 4065 4066 /* Get MAC address from config space if an eeprom exists, otherwise 4067 * the MAC address there will not be valid 4068 */ 4069 if (!adapter->has_eeprom) { 4070 et131x_hwaddr_init(adapter); 4071 return 0; 4072 } 4073 4074 for (i = 0; i < ETH_ALEN; i++) { 4075 if (pci_read_config_byte(pdev, ET1310_PCI_MAC_ADDRESS + i, 4076 adapter->rom_addr + i)) { 4077 dev_err(&pdev->dev, "Could not read PCI config space for MAC address\n"); 4078 goto err_out; 4079 } 4080 } 4081 memcpy(adapter->addr, adapter->rom_addr, ETH_ALEN); 4082out: 4083 return rc; 4084err_out: 4085 rc = -EIO; 4086 goto out; 4087} 4088 4089/** 4090 * et131x_error_timer_handler 4091 * @data: timer-specific variable; here a pointer to our adapter structure 4092 * 4093 * The routine called when the error timer expires, to track the number of 4094 * recurring errors. 4095 */ 4096static void et131x_error_timer_handler(unsigned long data) 4097{ 4098 struct et131x_adapter *adapter = (struct et131x_adapter *) data; 4099 struct phy_device *phydev = adapter->phydev; 4100 4101 if (et1310_in_phy_coma(adapter)) { 4102 /* Bring the device immediately out of coma, to 4103 * prevent it from sleeping indefinitely, this 4104 * mechanism could be improved! */ 4105 et1310_disable_phy_coma(adapter); 4106 adapter->boot_coma = 20; 4107 } else { 4108 et1310_update_macstat_host_counters(adapter); 4109 } 4110 4111 if (!phydev->link && adapter->boot_coma < 11) 4112 adapter->boot_coma++; 4113 4114 if (adapter->boot_coma == 10) { 4115 if (!phydev->link) { 4116 if (!et1310_in_phy_coma(adapter)) { 4117 /* NOTE - This was originally a 'sync with 4118 * interrupt'. How to do that under Linux? 4119 */ 4120 et131x_enable_interrupts(adapter); 4121 et1310_enable_phy_coma(adapter); 4122 } 4123 } 4124 } 4125 4126 /* This is a periodic timer, so reschedule */ 4127 mod_timer(&adapter->error_timer, jiffies + 4128 TX_ERROR_PERIOD * HZ / 1000); 4129} 4130 4131/** 4132 * et131x_adapter_memory_alloc 4133 * @adapter: pointer to our private adapter structure 4134 * 4135 * Returns 0 on success, errno on failure (as defined in errno.h). 4136 * 4137 * Allocate all the memory blocks for send, receive and others. 4138 */ 4139static int et131x_adapter_memory_alloc(struct et131x_adapter *adapter) 4140{ 4141 int status; 4142 4143 /* Allocate memory for the Tx Ring */ 4144 status = et131x_tx_dma_memory_alloc(adapter); 4145 if (status != 0) { 4146 dev_err(&adapter->pdev->dev, 4147 "et131x_tx_dma_memory_alloc FAILED\n"); 4148 return status; 4149 } 4150 /* Receive buffer memory allocation */ 4151 status = et131x_rx_dma_memory_alloc(adapter); 4152 if (status != 0) { 4153 dev_err(&adapter->pdev->dev, 4154 "et131x_rx_dma_memory_alloc FAILED\n"); 4155 et131x_tx_dma_memory_free(adapter); 4156 return status; 4157 } 4158 4159 /* Init receive data structures */ 4160 status = et131x_init_recv(adapter); 4161 if (status != 0) { 4162 dev_err(&adapter->pdev->dev, 4163 "et131x_init_recv FAILED\n"); 4164 et131x_tx_dma_memory_free(adapter); 4165 et131x_rx_dma_memory_free(adapter); 4166 } 4167 return status; 4168} 4169 4170/** 4171 * et131x_adapter_memory_free - Free all memory allocated for use by Tx & Rx 4172 * @adapter: pointer to our private adapter structure 4173 */ 4174static void et131x_adapter_memory_free(struct et131x_adapter *adapter) 4175{ 4176 /* Free DMA memory */ 4177 et131x_tx_dma_memory_free(adapter); 4178 et131x_rx_dma_memory_free(adapter); 4179} 4180 4181static void et131x_adjust_link(struct net_device *netdev) 4182{ 4183 struct et131x_adapter *adapter = netdev_priv(netdev); 4184 struct phy_device *phydev = adapter->phydev; 4185 4186 if (netif_carrier_ok(netdev)) { 4187 adapter->boot_coma = 20; 4188 4189 if (phydev && phydev->speed == SPEED_10) { 4190 /* 4191 * NOTE - Is there a way to query this without 4192 * TruePHY? 4193 * && TRU_QueryCoreType(adapter->hTruePhy, 0)== 4194 * EMI_TRUEPHY_A13O) { 4195 */ 4196 u16 register18; 4197 4198 et131x_mii_read(adapter, PHY_MPHY_CONTROL_REG, 4199 &register18); 4200 et131x_mii_write(adapter, PHY_MPHY_CONTROL_REG, 4201 register18 | 0x4); 4202 et131x_mii_write(adapter, PHY_INDEX_REG, 4203 register18 | 0x8402); 4204 et131x_mii_write(adapter, PHY_DATA_REG, 4205 register18 | 511); 4206 et131x_mii_write(adapter, PHY_MPHY_CONTROL_REG, 4207 register18); 4208 } 4209 4210 et1310_config_flow_control(adapter); 4211 4212 if (phydev && phydev->speed == SPEED_1000 && 4213 adapter->registry_jumbo_packet > 2048) { 4214 u16 reg; 4215 4216 et131x_mii_read(adapter, PHY_CONFIG, &reg); 4217 reg &= ~ET_PHY_CONFIG_TX_FIFO_DEPTH; 4218 reg |= ET_PHY_CONFIG_FIFO_DEPTH_32; 4219 et131x_mii_write(adapter, PHY_CONFIG, reg); 4220 } 4221 4222 et131x_set_rx_dma_timer(adapter); 4223 et1310_config_mac_regs2(adapter); 4224 } 4225 4226 if (phydev && phydev->link != adapter->link) { 4227 /* 4228 * Check to see if we are in coma mode and if 4229 * so, disable it because we will not be able 4230 * to read PHY values until we are out. 4231 */ 4232 if (et1310_in_phy_coma(adapter)) 4233 et1310_disable_phy_coma(adapter); 4234 4235 if (phydev->link) { 4236 adapter->boot_coma = 20; 4237 } else { 4238 dev_warn(&adapter->pdev->dev, 4239 "Link down - cable problem ?\n"); 4240 adapter->boot_coma = 0; 4241 4242 if (phydev->speed == SPEED_10) { 4243 /* NOTE - Is there a way to query this without 4244 * TruePHY? 4245 * && TRU_QueryCoreType(adapter->hTruePhy, 0) == 4246 * EMI_TRUEPHY_A13O) 4247 */ 4248 u16 register18; 4249 4250 et131x_mii_read(adapter, PHY_MPHY_CONTROL_REG, 4251 &register18); 4252 et131x_mii_write(adapter, PHY_MPHY_CONTROL_REG, 4253 register18 | 0x4); 4254 et131x_mii_write(adapter, PHY_INDEX_REG, 4255 register18 | 0x8402); 4256 et131x_mii_write(adapter, PHY_DATA_REG, 4257 register18 | 511); 4258 et131x_mii_write(adapter, PHY_MPHY_CONTROL_REG, 4259 register18); 4260 } 4261 4262 /* Free the packets being actively sent & stopped */ 4263 et131x_free_busy_send_packets(adapter); 4264 4265 /* Re-initialize the send structures */ 4266 et131x_init_send(adapter); 4267 4268 /* 4269 * Bring the device back to the state it was during 4270 * init prior to autonegotiation being complete. This 4271 * way, when we get the auto-neg complete interrupt, 4272 * we can complete init by calling config_mac_regs2. 4273 */ 4274 et131x_soft_reset(adapter); 4275 4276 /* Setup ET1310 as per the documentation */ 4277 et131x_adapter_setup(adapter); 4278 4279 /* perform reset of tx/rx */ 4280 et131x_disable_txrx(netdev); 4281 et131x_enable_txrx(netdev); 4282 } 4283 4284 adapter->link = phydev->link; 4285 4286 phy_print_status(phydev); 4287 } 4288} 4289 4290static int et131x_mii_probe(struct net_device *netdev) 4291{ 4292 struct et131x_adapter *adapter = netdev_priv(netdev); 4293 struct phy_device *phydev = NULL; 4294 4295 phydev = phy_find_first(adapter->mii_bus); 4296 if (!phydev) { 4297 dev_err(&adapter->pdev->dev, "no PHY found\n"); 4298 return -ENODEV; 4299 } 4300 4301 phydev = phy_connect(netdev, dev_name(&phydev->dev), 4302 &et131x_adjust_link, 0, PHY_INTERFACE_MODE_MII); 4303 4304 if (IS_ERR(phydev)) { 4305 dev_err(&adapter->pdev->dev, "Could not attach to PHY\n"); 4306 return PTR_ERR(phydev); 4307 } 4308 4309 phydev->supported &= (SUPPORTED_10baseT_Half 4310 | SUPPORTED_10baseT_Full 4311 | SUPPORTED_100baseT_Half 4312 | SUPPORTED_100baseT_Full 4313 | SUPPORTED_Autoneg 4314 | SUPPORTED_MII 4315 | SUPPORTED_TP); 4316 4317 if (adapter->pdev->device != ET131X_PCI_DEVICE_ID_FAST) 4318 phydev->supported |= SUPPORTED_1000baseT_Full; 4319 4320 phydev->advertising = phydev->supported; 4321 adapter->phydev = phydev; 4322 4323 dev_info(&adapter->pdev->dev, "attached PHY driver [%s] (mii_bus:phy_addr=%s)\n", 4324 phydev->drv->name, dev_name(&phydev->dev)); 4325 4326 return 0; 4327} 4328 4329/** 4330 * et131x_adapter_init 4331 * @adapter: pointer to the private adapter struct 4332 * @pdev: pointer to the PCI device 4333 * 4334 * Initialize the data structures for the et131x_adapter object and link 4335 * them together with the platform provided device structures. 4336 */ 4337static struct et131x_adapter *et131x_adapter_init(struct net_device *netdev, 4338 struct pci_dev *pdev) 4339{ 4340 static const u8 default_mac[] = { 0x00, 0x05, 0x3d, 0x00, 0x02, 0x00 }; 4341 4342 struct et131x_adapter *adapter; 4343 4344 /* Allocate private adapter struct and copy in relevant information */ 4345 adapter = netdev_priv(netdev); 4346 adapter->pdev = pci_dev_get(pdev); 4347 adapter->netdev = netdev; 4348 4349 /* Initialize spinlocks here */ 4350 spin_lock_init(&adapter->lock); 4351 spin_lock_init(&adapter->tcb_send_qlock); 4352 spin_lock_init(&adapter->tcb_ready_qlock); 4353 spin_lock_init(&adapter->send_hw_lock); 4354 spin_lock_init(&adapter->rcv_lock); 4355 spin_lock_init(&adapter->rcv_pend_lock); 4356 spin_lock_init(&adapter->fbr_lock); 4357 spin_lock_init(&adapter->phy_lock); 4358 4359 adapter->registry_jumbo_packet = 1514; /* 1514-9216 */ 4360 4361 /* Set the MAC address to a default */ 4362 memcpy(adapter->addr, default_mac, ETH_ALEN); 4363 4364 return adapter; 4365} 4366 4367/** 4368 * et131x_pci_remove 4369 * @pdev: a pointer to the device's pci_dev structure 4370 * 4371 * Registered in the pci_driver structure, this function is called when the 4372 * PCI subsystem detects that a PCI device which matches the information 4373 * contained in the pci_device_id table has been removed. 4374 */ 4375static void __devexit et131x_pci_remove(struct pci_dev *pdev) 4376{ 4377 struct net_device *netdev = pci_get_drvdata(pdev); 4378 struct et131x_adapter *adapter = netdev_priv(netdev); 4379 4380 unregister_netdev(netdev); 4381 phy_disconnect(adapter->phydev); 4382 mdiobus_unregister(adapter->mii_bus); 4383 kfree(adapter->mii_bus->irq); 4384 mdiobus_free(adapter->mii_bus); 4385 4386 et131x_adapter_memory_free(adapter); 4387 iounmap(adapter->regs); 4388 pci_dev_put(pdev); 4389 4390 free_netdev(netdev); 4391 pci_release_regions(pdev); 4392 pci_disable_device(pdev); 4393} 4394 4395/** 4396 * et131x_up - Bring up a device for use. 4397 * @netdev: device to be opened 4398 */ 4399static void et131x_up(struct net_device *netdev) 4400{ 4401 struct et131x_adapter *adapter = netdev_priv(netdev); 4402 4403 et131x_enable_txrx(netdev); 4404 phy_start(adapter->phydev); 4405} 4406 4407/** 4408 * et131x_down - Bring down the device 4409 * @netdev: device to be brought down 4410 */ 4411static void et131x_down(struct net_device *netdev) 4412{ 4413 struct et131x_adapter *adapter = netdev_priv(netdev); 4414 4415 /* Save the timestamp for the TX watchdog, prevent a timeout */ 4416 netdev->trans_start = jiffies; 4417 4418 phy_stop(adapter->phydev); 4419 et131x_disable_txrx(netdev); 4420} 4421 4422#ifdef CONFIG_PM_SLEEP 4423static int et131x_suspend(struct device *dev) 4424{ 4425 struct pci_dev *pdev = to_pci_dev(dev); 4426 struct net_device *netdev = pci_get_drvdata(pdev); 4427 4428 if (netif_running(netdev)) { 4429 netif_device_detach(netdev); 4430 et131x_down(netdev); 4431 pci_save_state(pdev); 4432 } 4433 4434 return 0; 4435} 4436 4437static int et131x_resume(struct device *dev) 4438{ 4439 struct pci_dev *pdev = to_pci_dev(dev); 4440 struct net_device *netdev = pci_get_drvdata(pdev); 4441 4442 if (netif_running(netdev)) { 4443 pci_restore_state(pdev); 4444 et131x_up(netdev); 4445 netif_device_attach(netdev); 4446 } 4447 4448 return 0; 4449} 4450 4451static SIMPLE_DEV_PM_OPS(et131x_pm_ops, et131x_suspend, et131x_resume); 4452#define ET131X_PM_OPS (&et131x_pm_ops) 4453#else 4454#define ET131X_PM_OPS NULL 4455#endif 4456 4457/** 4458 * et131x_isr - The Interrupt Service Routine for the driver. 4459 * @irq: the IRQ on which the interrupt was received. 4460 * @dev_id: device-specific info (here a pointer to a net_device struct) 4461 * 4462 * Returns a value indicating if the interrupt was handled. 4463 */ 4464irqreturn_t et131x_isr(int irq, void *dev_id) 4465{ 4466 bool handled = true; 4467 struct net_device *netdev = (struct net_device *)dev_id; 4468 struct et131x_adapter *adapter = NULL; 4469 u32 status; 4470 4471 if (!netif_device_present(netdev)) { 4472 handled = false; 4473 goto out; 4474 } 4475 4476 adapter = netdev_priv(netdev); 4477 4478 /* If the adapter is in low power state, then it should not 4479 * recognize any interrupt 4480 */ 4481 4482 /* Disable Device Interrupts */ 4483 et131x_disable_interrupts(adapter); 4484 4485 /* Get a copy of the value in the interrupt status register 4486 * so we can process the interrupting section 4487 */ 4488 status = readl(&adapter->regs->global.int_status); 4489 4490 if (adapter->flowcontrol == FLOW_TXONLY || 4491 adapter->flowcontrol == FLOW_BOTH) { 4492 status &= ~INT_MASK_ENABLE; 4493 } else { 4494 status &= ~INT_MASK_ENABLE_NO_FLOW; 4495 } 4496 4497 /* Make sure this is our interrupt */ 4498 if (!status) { 4499 handled = false; 4500 et131x_enable_interrupts(adapter); 4501 goto out; 4502 } 4503 4504 /* This is our interrupt, so process accordingly */ 4505 4506 if (status & ET_INTR_WATCHDOG) { 4507 struct tcb *tcb = adapter->tx_ring.send_head; 4508 4509 if (tcb) 4510 if (++tcb->stale > 1) 4511 status |= ET_INTR_TXDMA_ISR; 4512 4513 if (adapter->rx_ring.unfinished_receives) 4514 status |= ET_INTR_RXDMA_XFR_DONE; 4515 else if (tcb == NULL) 4516 writel(0, &adapter->regs->global.watchdog_timer); 4517 4518 status &= ~ET_INTR_WATCHDOG; 4519 } 4520 4521 if (status == 0) { 4522 /* This interrupt has in some way been "handled" by 4523 * the ISR. Either it was a spurious Rx interrupt, or 4524 * it was a Tx interrupt that has been filtered by 4525 * the ISR. 4526 */ 4527 et131x_enable_interrupts(adapter); 4528 goto out; 4529 } 4530 4531 /* We need to save the interrupt status value for use in our 4532 * DPC. We will clear the software copy of that in that 4533 * routine. 4534 */ 4535 adapter->stats.interrupt_status = status; 4536 4537 /* Schedule the ISR handler as a bottom-half task in the 4538 * kernel's tq_immediate queue, and mark the queue for 4539 * execution 4540 */ 4541 schedule_work(&adapter->task); 4542out: 4543 return IRQ_RETVAL(handled); 4544} 4545 4546/** 4547 * et131x_isr_handler - The ISR handler 4548 * @p_adapter, a pointer to the device's private adapter structure 4549 * 4550 * scheduled to run in a deferred context by the ISR. This is where the ISR's 4551 * work actually gets done. 4552 */ 4553static void et131x_isr_handler(struct work_struct *work) 4554{ 4555 struct et131x_adapter *adapter = 4556 container_of(work, struct et131x_adapter, task); 4557 u32 status = adapter->stats.interrupt_status; 4558 struct address_map __iomem *iomem = adapter->regs; 4559 4560 /* 4561 * These first two are by far the most common. Once handled, we clear 4562 * their two bits in the status word. If the word is now zero, we 4563 * exit. 4564 */ 4565 /* Handle all the completed Transmit interrupts */ 4566 if (status & ET_INTR_TXDMA_ISR) 4567 et131x_handle_send_interrupt(adapter); 4568 4569 /* Handle all the completed Receives interrupts */ 4570 if (status & ET_INTR_RXDMA_XFR_DONE) 4571 et131x_handle_recv_interrupt(adapter); 4572 4573 status &= 0xffffffd7; 4574 4575 if (status) { 4576 /* Handle the TXDMA Error interrupt */ 4577 if (status & ET_INTR_TXDMA_ERR) { 4578 u32 txdma_err; 4579 4580 /* Following read also clears the register (COR) */ 4581 txdma_err = readl(&iomem->txdma.tx_dma_error); 4582 4583 dev_warn(&adapter->pdev->dev, 4584 "TXDMA_ERR interrupt, error = %d\n", 4585 txdma_err); 4586 } 4587 4588 /* Handle Free Buffer Ring 0 and 1 Low interrupt */ 4589 if (status & 4590 (ET_INTR_RXDMA_FB_R0_LOW | ET_INTR_RXDMA_FB_R1_LOW)) { 4591 /* 4592 * This indicates the number of unused buffers in 4593 * RXDMA free buffer ring 0 is <= the limit you 4594 * programmed. Free buffer resources need to be 4595 * returned. Free buffers are consumed as packets 4596 * are passed from the network to the host. The host 4597 * becomes aware of the packets from the contents of 4598 * the packet status ring. This ring is queried when 4599 * the packet done interrupt occurs. Packets are then 4600 * passed to the OS. When the OS is done with the 4601 * packets the resources can be returned to the 4602 * ET1310 for re-use. This interrupt is one method of 4603 * returning resources. 4604 */ 4605 4606 /* If the user has flow control on, then we will 4607 * send a pause packet, otherwise just exit 4608 */ 4609 if (adapter->flowcontrol == FLOW_TXONLY || 4610 adapter->flowcontrol == FLOW_BOTH) { 4611 u32 pm_csr; 4612 4613 /* Tell the device to send a pause packet via 4614 * the back pressure register (bp req and 4615 * bp xon/xoff) 4616 */ 4617 pm_csr = readl(&iomem->global.pm_csr); 4618 if (!et1310_in_phy_coma(adapter)) 4619 writel(3, &iomem->txmac.bp_ctrl); 4620 } 4621 } 4622 4623 /* Handle Packet Status Ring Low Interrupt */ 4624 if (status & ET_INTR_RXDMA_STAT_LOW) { 4625 4626 /* 4627 * Same idea as with the two Free Buffer Rings. 4628 * Packets going from the network to the host each 4629 * consume a free buffer resource and a packet status 4630 * resource. These resoures are passed to the OS. 4631 * When the OS is done with the resources, they need 4632 * to be returned to the ET1310. This is one method 4633 * of returning the resources. 4634 */ 4635 } 4636 4637 /* Handle RXDMA Error Interrupt */ 4638 if (status & ET_INTR_RXDMA_ERR) { 4639 /* 4640 * The rxdma_error interrupt is sent when a time-out 4641 * on a request issued by the JAGCore has occurred or 4642 * a completion is returned with an un-successful 4643 * status. In both cases the request is considered 4644 * complete. The JAGCore will automatically re-try the 4645 * request in question. Normally information on events 4646 * like these are sent to the host using the "Advanced 4647 * Error Reporting" capability. This interrupt is 4648 * another way of getting similar information. The 4649 * only thing required is to clear the interrupt by 4650 * reading the ISR in the global resources. The 4651 * JAGCore will do a re-try on the request. Normally 4652 * you should never see this interrupt. If you start 4653 * to see this interrupt occurring frequently then 4654 * something bad has occurred. A reset might be the 4655 * thing to do. 4656 */ 4657 /* TRAP();*/ 4658 4659 dev_warn(&adapter->pdev->dev, 4660 "RxDMA_ERR interrupt, error %x\n", 4661 readl(&iomem->txmac.tx_test)); 4662 } 4663 4664 /* Handle the Wake on LAN Event */ 4665 if (status & ET_INTR_WOL) { 4666 /* 4667 * This is a secondary interrupt for wake on LAN. 4668 * The driver should never see this, if it does, 4669 * something serious is wrong. We will TRAP the 4670 * message when we are in DBG mode, otherwise we 4671 * will ignore it. 4672 */ 4673 dev_err(&adapter->pdev->dev, "WAKE_ON_LAN interrupt\n"); 4674 } 4675 4676 /* Let's move on to the TxMac */ 4677 if (status & ET_INTR_TXMAC) { 4678 u32 err = readl(&iomem->txmac.err); 4679 4680 /* 4681 * When any of the errors occur and TXMAC generates 4682 * an interrupt to report these errors, it usually 4683 * means that TXMAC has detected an error in the data 4684 * stream retrieved from the on-chip Tx Q. All of 4685 * these errors are catastrophic and TXMAC won't be 4686 * able to recover data when these errors occur. In 4687 * a nutshell, the whole Tx path will have to be reset 4688 * and re-configured afterwards. 4689 */ 4690 dev_warn(&adapter->pdev->dev, 4691 "TXMAC interrupt, error 0x%08x\n", 4692 err); 4693 4694 /* If we are debugging, we want to see this error, 4695 * otherwise we just want the device to be reset and 4696 * continue 4697 */ 4698 } 4699 4700 /* Handle RXMAC Interrupt */ 4701 if (status & ET_INTR_RXMAC) { 4702 /* 4703 * These interrupts are catastrophic to the device, 4704 * what we need to do is disable the interrupts and 4705 * set the flag to cause us to reset so we can solve 4706 * this issue. 4707 */ 4708 /* MP_SET_FLAG( adapter, 4709 fMP_ADAPTER_HARDWARE_ERROR); */ 4710 4711 dev_warn(&adapter->pdev->dev, 4712 "RXMAC interrupt, error 0x%08x. Requesting reset\n", 4713 readl(&iomem->rxmac.err_reg)); 4714 4715 dev_warn(&adapter->pdev->dev, 4716 "Enable 0x%08x, Diag 0x%08x\n", 4717 readl(&iomem->rxmac.ctrl), 4718 readl(&iomem->rxmac.rxq_diag)); 4719 4720 /* 4721 * If we are debugging, we want to see this error, 4722 * otherwise we just want the device to be reset and 4723 * continue 4724 */ 4725 } 4726 4727 /* Handle MAC_STAT Interrupt */ 4728 if (status & ET_INTR_MAC_STAT) { 4729 /* 4730 * This means at least one of the un-masked counters 4731 * in the MAC_STAT block has rolled over. Use this 4732 * to maintain the top, software managed bits of the 4733 * counter(s). 4734 */ 4735 et1310_handle_macstat_interrupt(adapter); 4736 } 4737 4738 /* Handle SLV Timeout Interrupt */ 4739 if (status & ET_INTR_SLV_TIMEOUT) { 4740 /* 4741 * This means a timeout has occurred on a read or 4742 * write request to one of the JAGCore registers. The 4743 * Global Resources block has terminated the request 4744 * and on a read request, returned a "fake" value. 4745 * The most likely reasons are: Bad Address or the 4746 * addressed module is in a power-down state and 4747 * can't respond. 4748 */ 4749 } 4750 } 4751 et131x_enable_interrupts(adapter); 4752} 4753 4754/** 4755 * et131x_stats - Return the current device statistics. 4756 * @netdev: device whose stats are being queried 4757 * 4758 * Returns 0 on success, errno on failure (as defined in errno.h) 4759 */ 4760static struct net_device_stats *et131x_stats(struct net_device *netdev) 4761{ 4762 struct et131x_adapter *adapter = netdev_priv(netdev); 4763 struct net_device_stats *stats = &adapter->net_stats; 4764 struct ce_stats *devstat = &adapter->stats; 4765 4766 stats->rx_errors = devstat->rx_length_errs + 4767 devstat->rx_align_errs + 4768 devstat->rx_crc_errs + 4769 devstat->rx_code_violations + 4770 devstat->rx_other_errs; 4771 stats->tx_errors = devstat->tx_max_pkt_errs; 4772 stats->multicast = devstat->multicast_pkts_rcvd; 4773 stats->collisions = devstat->tx_collisions; 4774 4775 stats->rx_length_errors = devstat->rx_length_errs; 4776 stats->rx_over_errors = devstat->rx_overflows; 4777 stats->rx_crc_errors = devstat->rx_crc_errs; 4778 4779 /* NOTE: These stats don't have corresponding values in CE_STATS, 4780 * so we're going to have to update these directly from within the 4781 * TX/RX code 4782 */ 4783 /* stats->rx_bytes = 20; devstat->; */ 4784 /* stats->tx_bytes = 20; devstat->; */ 4785 /* stats->rx_dropped = devstat->; */ 4786 /* stats->tx_dropped = devstat->; */ 4787 4788 /* NOTE: Not used, can't find analogous statistics */ 4789 /* stats->rx_frame_errors = devstat->; */ 4790 /* stats->rx_fifo_errors = devstat->; */ 4791 /* stats->rx_missed_errors = devstat->; */ 4792 4793 /* stats->tx_aborted_errors = devstat->; */ 4794 /* stats->tx_carrier_errors = devstat->; */ 4795 /* stats->tx_fifo_errors = devstat->; */ 4796 /* stats->tx_heartbeat_errors = devstat->; */ 4797 /* stats->tx_window_errors = devstat->; */ 4798 return stats; 4799} 4800 4801/** 4802 * et131x_open - Open the device for use. 4803 * @netdev: device to be opened 4804 * 4805 * Returns 0 on success, errno on failure (as defined in errno.h) 4806 */ 4807static int et131x_open(struct net_device *netdev) 4808{ 4809 struct et131x_adapter *adapter = netdev_priv(netdev); 4810 struct pci_dev *pdev = adapter->pdev; 4811 unsigned int irq = pdev->irq; 4812 int result; 4813 4814 /* Start the timer to track NIC errors */ 4815 init_timer(&adapter->error_timer); 4816 adapter->error_timer.expires = jiffies + TX_ERROR_PERIOD * HZ / 1000; 4817 adapter->error_timer.function = et131x_error_timer_handler; 4818 adapter->error_timer.data = (unsigned long)adapter; 4819 add_timer(&adapter->error_timer); 4820 4821 result = request_irq(irq, et131x_isr, 4822 IRQF_SHARED, netdev->name, netdev); 4823 if (result) { 4824 dev_err(&pdev->dev, "could not register IRQ %d\n", irq); 4825 return result; 4826 } 4827 4828 adapter->flags |= fMP_ADAPTER_INTERRUPT_IN_USE; 4829 4830 et131x_up(netdev); 4831 4832 return result; 4833} 4834 4835/** 4836 * et131x_close - Close the device 4837 * @netdev: device to be closed 4838 * 4839 * Returns 0 on success, errno on failure (as defined in errno.h) 4840 */ 4841static int et131x_close(struct net_device *netdev) 4842{ 4843 struct et131x_adapter *adapter = netdev_priv(netdev); 4844 4845 et131x_down(netdev); 4846 4847 adapter->flags &= ~fMP_ADAPTER_INTERRUPT_IN_USE; 4848 free_irq(adapter->pdev->irq, netdev); 4849 4850 /* Stop the error timer */ 4851 return del_timer_sync(&adapter->error_timer); 4852} 4853 4854/** 4855 * et131x_ioctl - The I/O Control handler for the driver 4856 * @netdev: device on which the control request is being made 4857 * @reqbuf: a pointer to the IOCTL request buffer 4858 * @cmd: the IOCTL command code 4859 * 4860 * Returns 0 on success, errno on failure (as defined in errno.h) 4861 */ 4862static int et131x_ioctl(struct net_device *netdev, struct ifreq *reqbuf, 4863 int cmd) 4864{ 4865 struct et131x_adapter *adapter = netdev_priv(netdev); 4866 4867 if (!adapter->phydev) 4868 return -EINVAL; 4869 4870 return phy_mii_ioctl(adapter->phydev, reqbuf, cmd); 4871} 4872 4873/** 4874 * et131x_set_packet_filter - Configures the Rx Packet filtering on the device 4875 * @adapter: pointer to our private adapter structure 4876 * 4877 * FIXME: lot of dups with MAC code 4878 * 4879 * Returns 0 on success, errno on failure 4880 */ 4881static int et131x_set_packet_filter(struct et131x_adapter *adapter) 4882{ 4883 int filter = adapter->packet_filter; 4884 int status = 0; 4885 u32 ctrl; 4886 u32 pf_ctrl; 4887 4888 ctrl = readl(&adapter->regs->rxmac.ctrl); 4889 pf_ctrl = readl(&adapter->regs->rxmac.pf_ctrl); 4890 4891 /* Default to disabled packet filtering. Enable it in the individual 4892 * case statements that require the device to filter something 4893 */ 4894 ctrl |= 0x04; 4895 4896 /* Set us to be in promiscuous mode so we receive everything, this 4897 * is also true when we get a packet filter of 0 4898 */ 4899 if ((filter & ET131X_PACKET_TYPE_PROMISCUOUS) || filter == 0) 4900 pf_ctrl &= ~7; /* Clear filter bits */ 4901 else { 4902 /* 4903 * Set us up with Multicast packet filtering. Three cases are 4904 * possible - (1) we have a multi-cast list, (2) we receive ALL 4905 * multicast entries or (3) we receive none. 4906 */ 4907 if (filter & ET131X_PACKET_TYPE_ALL_MULTICAST) 4908 pf_ctrl &= ~2; /* Multicast filter bit */ 4909 else { 4910 et1310_setup_device_for_multicast(adapter); 4911 pf_ctrl |= 2; 4912 ctrl &= ~0x04; 4913 } 4914 4915 /* Set us up with Unicast packet filtering */ 4916 if (filter & ET131X_PACKET_TYPE_DIRECTED) { 4917 et1310_setup_device_for_unicast(adapter); 4918 pf_ctrl |= 4; 4919 ctrl &= ~0x04; 4920 } 4921 4922 /* Set us up with Broadcast packet filtering */ 4923 if (filter & ET131X_PACKET_TYPE_BROADCAST) { 4924 pf_ctrl |= 1; /* Broadcast filter bit */ 4925 ctrl &= ~0x04; 4926 } else 4927 pf_ctrl &= ~1; 4928 4929 /* Setup the receive mac configuration registers - Packet 4930 * Filter control + the enable / disable for packet filter 4931 * in the control reg. 4932 */ 4933 writel(pf_ctrl, &adapter->regs->rxmac.pf_ctrl); 4934 writel(ctrl, &adapter->regs->rxmac.ctrl); 4935 } 4936 return status; 4937} 4938 4939/** 4940 * et131x_multicast - The handler to configure multicasting on the interface 4941 * @netdev: a pointer to a net_device struct representing the device 4942 */ 4943static void et131x_multicast(struct net_device *netdev) 4944{ 4945 struct et131x_adapter *adapter = netdev_priv(netdev); 4946 int packet_filter; 4947 unsigned long flags; 4948 struct netdev_hw_addr *ha; 4949 int i; 4950 4951 spin_lock_irqsave(&adapter->lock, flags); 4952 4953 /* Before we modify the platform-independent filter flags, store them 4954 * locally. This allows us to determine if anything's changed and if 4955 * we even need to bother the hardware 4956 */ 4957 packet_filter = adapter->packet_filter; 4958 4959 /* Clear the 'multicast' flag locally; because we only have a single 4960 * flag to check multicast, and multiple multicast addresses can be 4961 * set, this is the easiest way to determine if more than one 4962 * multicast address is being set. 4963 */ 4964 packet_filter &= ~ET131X_PACKET_TYPE_MULTICAST; 4965 4966 /* Check the net_device flags and set the device independent flags 4967 * accordingly 4968 */ 4969 4970 if (netdev->flags & IFF_PROMISC) 4971 adapter->packet_filter |= ET131X_PACKET_TYPE_PROMISCUOUS; 4972 else 4973 adapter->packet_filter &= ~ET131X_PACKET_TYPE_PROMISCUOUS; 4974 4975 if (netdev->flags & IFF_ALLMULTI) 4976 adapter->packet_filter |= ET131X_PACKET_TYPE_ALL_MULTICAST; 4977 4978 if (netdev_mc_count(netdev) > NIC_MAX_MCAST_LIST) 4979 adapter->packet_filter |= ET131X_PACKET_TYPE_ALL_MULTICAST; 4980 4981 if (netdev_mc_count(netdev) < 1) { 4982 adapter->packet_filter &= ~ET131X_PACKET_TYPE_ALL_MULTICAST; 4983 adapter->packet_filter &= ~ET131X_PACKET_TYPE_MULTICAST; 4984 } else 4985 adapter->packet_filter |= ET131X_PACKET_TYPE_MULTICAST; 4986 4987 /* Set values in the private adapter struct */ 4988 i = 0; 4989 netdev_for_each_mc_addr(ha, netdev) { 4990 if (i == NIC_MAX_MCAST_LIST) 4991 break; 4992 memcpy(adapter->multicast_list[i++], ha->addr, ETH_ALEN); 4993 } 4994 adapter->multicast_addr_count = i; 4995 4996 /* Are the new flags different from the previous ones? If not, then no 4997 * action is required 4998 * 4999 * NOTE - This block will always update the multicast_list with the 5000 * hardware, even if the addresses aren't the same. 5001 */ 5002 if (packet_filter != adapter->packet_filter) { 5003 /* Call the device's filter function */ 5004 et131x_set_packet_filter(adapter); 5005 } 5006 spin_unlock_irqrestore(&adapter->lock, flags); 5007} 5008 5009/** 5010 * et131x_tx - The handler to tx a packet on the device 5011 * @skb: data to be Tx'd 5012 * @netdev: device on which data is to be Tx'd 5013 * 5014 * Returns 0 on success, errno on failure (as defined in errno.h) 5015 */ 5016static int et131x_tx(struct sk_buff *skb, struct net_device *netdev) 5017{ 5018 int status = 0; 5019 struct et131x_adapter *adapter = netdev_priv(netdev); 5020 5021 /* stop the queue if it's getting full */ 5022 if (adapter->tx_ring.used >= NUM_TCB - 1 && 5023 !netif_queue_stopped(netdev)) 5024 netif_stop_queue(netdev); 5025 5026 /* Save the timestamp for the TX timeout watchdog */ 5027 netdev->trans_start = jiffies; 5028 5029 /* Call the device-specific data Tx routine */ 5030 status = et131x_send_packets(skb, netdev); 5031 5032 /* Check status and manage the netif queue if necessary */ 5033 if (status != 0) { 5034 if (status == -ENOMEM) 5035 status = NETDEV_TX_BUSY; 5036 else 5037 status = NETDEV_TX_OK; 5038 } 5039 return status; 5040} 5041 5042/** 5043 * et131x_tx_timeout - Timeout handler 5044 * @netdev: a pointer to a net_device struct representing the device 5045 * 5046 * The handler called when a Tx request times out. The timeout period is 5047 * specified by the 'tx_timeo" element in the net_device structure (see 5048 * et131x_alloc_device() to see how this value is set). 5049 */ 5050static void et131x_tx_timeout(struct net_device *netdev) 5051{ 5052 struct et131x_adapter *adapter = netdev_priv(netdev); 5053 struct tcb *tcb; 5054 unsigned long flags; 5055 5056 /* If the device is closed, ignore the timeout */ 5057 if (~(adapter->flags & fMP_ADAPTER_INTERRUPT_IN_USE)) 5058 return; 5059 5060 /* Any nonrecoverable hardware error? 5061 * Checks adapter->flags for any failure in phy reading 5062 */ 5063 if (adapter->flags & fMP_ADAPTER_NON_RECOVER_ERROR) 5064 return; 5065 5066 /* Hardware failure? */ 5067 if (adapter->flags & fMP_ADAPTER_HARDWARE_ERROR) { 5068 dev_err(&adapter->pdev->dev, "hardware error - reset\n"); 5069 return; 5070 } 5071 5072 /* Is send stuck? */ 5073 spin_lock_irqsave(&adapter->tcb_send_qlock, flags); 5074 5075 tcb = adapter->tx_ring.send_head; 5076 5077 if (tcb != NULL) { 5078 tcb->count++; 5079 5080 if (tcb->count > NIC_SEND_HANG_THRESHOLD) { 5081 spin_unlock_irqrestore(&adapter->tcb_send_qlock, 5082 flags); 5083 5084 dev_warn(&adapter->pdev->dev, 5085 "Send stuck - reset. tcb->WrIndex %x, flags 0x%08x\n", 5086 tcb->index, 5087 tcb->flags); 5088 5089 adapter->net_stats.tx_errors++; 5090 5091 /* perform reset of tx/rx */ 5092 et131x_disable_txrx(netdev); 5093 et131x_enable_txrx(netdev); 5094 return; 5095 } 5096 } 5097 5098 spin_unlock_irqrestore(&adapter->tcb_send_qlock, flags); 5099} 5100 5101/** 5102 * et131x_change_mtu - The handler called to change the MTU for the device 5103 * @netdev: device whose MTU is to be changed 5104 * @new_mtu: the desired MTU 5105 * 5106 * Returns 0 on success, errno on failure (as defined in errno.h) 5107 */ 5108static int et131x_change_mtu(struct net_device *netdev, int new_mtu) 5109{ 5110 int result = 0; 5111 struct et131x_adapter *adapter = netdev_priv(netdev); 5112 5113 /* Make sure the requested MTU is valid */ 5114 if (new_mtu < 64 || new_mtu > 9216) 5115 return -EINVAL; 5116 5117 et131x_disable_txrx(netdev); 5118 et131x_handle_send_interrupt(adapter); 5119 et131x_handle_recv_interrupt(adapter); 5120 5121 /* Set the new MTU */ 5122 netdev->mtu = new_mtu; 5123 5124 /* Free Rx DMA memory */ 5125 et131x_adapter_memory_free(adapter); 5126 5127 /* Set the config parameter for Jumbo Packet support */ 5128 adapter->registry_jumbo_packet = new_mtu + 14; 5129 et131x_soft_reset(adapter); 5130 5131 /* Alloc and init Rx DMA memory */ 5132 result = et131x_adapter_memory_alloc(adapter); 5133 if (result != 0) { 5134 dev_warn(&adapter->pdev->dev, 5135 "Change MTU failed; couldn't re-alloc DMA memory\n"); 5136 return result; 5137 } 5138 5139 et131x_init_send(adapter); 5140 5141 et131x_hwaddr_init(adapter); 5142 memcpy(netdev->dev_addr, adapter->addr, ETH_ALEN); 5143 5144 /* Init the device with the new settings */ 5145 et131x_adapter_setup(adapter); 5146 5147 et131x_enable_txrx(netdev); 5148 5149 return result; 5150} 5151 5152/** 5153 * et131x_set_mac_addr - handler to change the MAC address for the device 5154 * @netdev: device whose MAC is to be changed 5155 * @new_mac: the desired MAC address 5156 * 5157 * Returns 0 on success, errno on failure (as defined in errno.h) 5158 * 5159 * IMPLEMENTED BY : blux http://berndlux.de 22.01.2007 21:14 5160 */ 5161static int et131x_set_mac_addr(struct net_device *netdev, void *new_mac) 5162{ 5163 int result = 0; 5164 struct et131x_adapter *adapter = netdev_priv(netdev); 5165 struct sockaddr *address = new_mac; 5166 5167 /* begin blux */ 5168 5169 if (adapter == NULL) 5170 return -ENODEV; 5171 5172 /* Make sure the requested MAC is valid */ 5173 if (!is_valid_ether_addr(address->sa_data)) 5174 return -EADDRNOTAVAIL; 5175 5176 et131x_disable_txrx(netdev); 5177 et131x_handle_send_interrupt(adapter); 5178 et131x_handle_recv_interrupt(adapter); 5179 5180 /* Set the new MAC */ 5181 /* netdev->set_mac_address = &new_mac; */ 5182 5183 memcpy(netdev->dev_addr, address->sa_data, netdev->addr_len); 5184 5185 netdev_info(netdev, "Setting MAC address to %pM\n", 5186 netdev->dev_addr); 5187 5188 /* Free Rx DMA memory */ 5189 et131x_adapter_memory_free(adapter); 5190 5191 et131x_soft_reset(adapter); 5192 5193 /* Alloc and init Rx DMA memory */ 5194 result = et131x_adapter_memory_alloc(adapter); 5195 if (result != 0) { 5196 dev_err(&adapter->pdev->dev, 5197 "Change MAC failed; couldn't re-alloc DMA memory\n"); 5198 return result; 5199 } 5200 5201 et131x_init_send(adapter); 5202 5203 et131x_hwaddr_init(adapter); 5204 5205 /* Init the device with the new settings */ 5206 et131x_adapter_setup(adapter); 5207 5208 et131x_enable_txrx(netdev); 5209 5210 return result; 5211} 5212 5213static const struct net_device_ops et131x_netdev_ops = { 5214 .ndo_open = et131x_open, 5215 .ndo_stop = et131x_close, 5216 .ndo_start_xmit = et131x_tx, 5217 .ndo_set_rx_mode = et131x_multicast, 5218 .ndo_tx_timeout = et131x_tx_timeout, 5219 .ndo_change_mtu = et131x_change_mtu, 5220 .ndo_set_mac_address = et131x_set_mac_addr, 5221 .ndo_validate_addr = eth_validate_addr, 5222 .ndo_get_stats = et131x_stats, 5223 .ndo_do_ioctl = et131x_ioctl, 5224}; 5225 5226/** 5227 * et131x_pci_setup - Perform device initialization 5228 * @pdev: a pointer to the device's pci_dev structure 5229 * @ent: this device's entry in the pci_device_id table 5230 * 5231 * Returns 0 on success, errno on failure (as defined in errno.h) 5232 * 5233 * Registered in the pci_driver structure, this function is called when the 5234 * PCI subsystem finds a new PCI device which matches the information 5235 * contained in the pci_device_id table. This routine is the equivalent to 5236 * a device insertion routine. 5237 */ 5238static int __devinit et131x_pci_setup(struct pci_dev *pdev, 5239 const struct pci_device_id *ent) 5240{ 5241 struct net_device *netdev; 5242 struct et131x_adapter *adapter; 5243 int rc; 5244 int ii; 5245 5246 rc = pci_enable_device(pdev); 5247 if (rc < 0) { 5248 dev_err(&pdev->dev, "pci_enable_device() failed\n"); 5249 goto out; 5250 } 5251 5252 /* Perform some basic PCI checks */ 5253 if (!(pci_resource_flags(pdev, 0) & IORESOURCE_MEM)) { 5254 dev_err(&pdev->dev, "Can't find PCI device's base address\n"); 5255 rc = -ENODEV; 5256 goto err_disable; 5257 } 5258 5259 rc = pci_request_regions(pdev, DRIVER_NAME); 5260 if (rc < 0) { 5261 dev_err(&pdev->dev, "Can't get PCI resources\n"); 5262 goto err_disable; 5263 } 5264 5265 pci_set_master(pdev); 5266 5267 /* Check the DMA addressing support of this device */ 5268 if (!dma_set_mask(&pdev->dev, DMA_BIT_MASK(64))) { 5269 rc = dma_set_coherent_mask(&pdev->dev, DMA_BIT_MASK(64)); 5270 if (rc < 0) { 5271 dev_err(&pdev->dev, 5272 "Unable to obtain 64 bit DMA for consistent allocations\n"); 5273 goto err_release_res; 5274 } 5275 } else if (!dma_set_mask(&pdev->dev, DMA_BIT_MASK(32))) { 5276 rc = dma_set_coherent_mask(&pdev->dev, DMA_BIT_MASK(32)); 5277 if (rc < 0) { 5278 dev_err(&pdev->dev, 5279 "Unable to obtain 32 bit DMA for consistent allocations\n"); 5280 goto err_release_res; 5281 } 5282 } else { 5283 dev_err(&pdev->dev, "No usable DMA addressing method\n"); 5284 rc = -EIO; 5285 goto err_release_res; 5286 } 5287 5288 /* Allocate netdev and private adapter structs */ 5289 netdev = alloc_etherdev(sizeof(struct et131x_adapter)); 5290 if (!netdev) { 5291 dev_err(&pdev->dev, "Couldn't alloc netdev struct\n"); 5292 rc = -ENOMEM; 5293 goto err_release_res; 5294 } 5295 5296 netdev->watchdog_timeo = ET131X_TX_TIMEOUT; 5297 netdev->netdev_ops = &et131x_netdev_ops; 5298 5299 SET_NETDEV_DEV(netdev, &pdev->dev); 5300 SET_ETHTOOL_OPS(netdev, &et131x_ethtool_ops); 5301 5302 adapter = et131x_adapter_init(netdev, pdev); 5303 5304 rc = et131x_pci_init(adapter, pdev); 5305 if (rc < 0) 5306 goto err_free_dev; 5307 5308 /* Map the bus-relative registers to system virtual memory */ 5309 adapter->regs = pci_ioremap_bar(pdev, 0); 5310 if (!adapter->regs) { 5311 dev_err(&pdev->dev, "Cannot map device registers\n"); 5312 rc = -ENOMEM; 5313 goto err_free_dev; 5314 } 5315 5316 /* If Phy COMA mode was enabled when we went down, disable it here. */ 5317 writel(ET_PMCSR_INIT, &adapter->regs->global.pm_csr); 5318 5319 /* Issue a global reset to the et1310 */ 5320 et131x_soft_reset(adapter); 5321 5322 /* Disable all interrupts (paranoid) */ 5323 et131x_disable_interrupts(adapter); 5324 5325 /* Allocate DMA memory */ 5326 rc = et131x_adapter_memory_alloc(adapter); 5327 if (rc < 0) { 5328 dev_err(&pdev->dev, "Could not alloc adapater memory (DMA)\n"); 5329 goto err_iounmap; 5330 } 5331 5332 /* Init send data structures */ 5333 et131x_init_send(adapter); 5334 5335 /* Set up the task structure for the ISR's deferred handler */ 5336 INIT_WORK(&adapter->task, et131x_isr_handler); 5337 5338 /* Copy address into the net_device struct */ 5339 memcpy(netdev->dev_addr, adapter->addr, ETH_ALEN); 5340 5341 /* Init variable for counting how long we do not have link status */ 5342 adapter->boot_coma = 0; 5343 et1310_disable_phy_coma(adapter); 5344 5345 rc = -ENOMEM; 5346 5347 /* Setup the mii_bus struct */ 5348 adapter->mii_bus = mdiobus_alloc(); 5349 if (!adapter->mii_bus) { 5350 dev_err(&pdev->dev, "Alloc of mii_bus struct failed\n"); 5351 goto err_mem_free; 5352 } 5353 5354 adapter->mii_bus->name = "et131x_eth_mii"; 5355 snprintf(adapter->mii_bus->id, MII_BUS_ID_SIZE, "%x", 5356 (adapter->pdev->bus->number << 8) | adapter->pdev->devfn); 5357 adapter->mii_bus->priv = netdev; 5358 adapter->mii_bus->read = et131x_mdio_read; 5359 adapter->mii_bus->write = et131x_mdio_write; 5360 adapter->mii_bus->reset = et131x_mdio_reset; 5361 adapter->mii_bus->irq = kmalloc(sizeof(int)*PHY_MAX_ADDR, GFP_KERNEL); 5362 if (!adapter->mii_bus->irq) { 5363 dev_err(&pdev->dev, "mii_bus irq allocation failed\n"); 5364 goto err_mdio_free; 5365 } 5366 5367 for (ii = 0; ii < PHY_MAX_ADDR; ii++) 5368 adapter->mii_bus->irq[ii] = PHY_POLL; 5369 5370 rc = mdiobus_register(adapter->mii_bus); 5371 if (rc < 0) { 5372 dev_err(&pdev->dev, "failed to register MII bus\n"); 5373 goto err_mdio_free_irq; 5374 } 5375 5376 rc = et131x_mii_probe(netdev); 5377 if (rc < 0) { 5378 dev_err(&pdev->dev, "failed to probe MII bus\n"); 5379 goto err_mdio_unregister; 5380 } 5381 5382 /* Setup et1310 as per the documentation */ 5383 et131x_adapter_setup(adapter); 5384 5385 /* We can enable interrupts now 5386 * 5387 * NOTE - Because registration of interrupt handler is done in the 5388 * device's open(), defer enabling device interrupts to that 5389 * point 5390 */ 5391 5392 /* Register the net_device struct with the Linux network layer */ 5393 rc = register_netdev(netdev); 5394 if (rc < 0) { 5395 dev_err(&pdev->dev, "register_netdev() failed\n"); 5396 goto err_phy_disconnect; 5397 } 5398 5399 /* Register the net_device struct with the PCI subsystem. Save a copy 5400 * of the PCI config space for this device now that the device has 5401 * been initialized, just in case it needs to be quickly restored. 5402 */ 5403 pci_set_drvdata(pdev, netdev); 5404out: 5405 return rc; 5406 5407err_phy_disconnect: 5408 phy_disconnect(adapter->phydev); 5409err_mdio_unregister: 5410 mdiobus_unregister(adapter->mii_bus); 5411err_mdio_free_irq: 5412 kfree(adapter->mii_bus->irq); 5413err_mdio_free: 5414 mdiobus_free(adapter->mii_bus); 5415err_mem_free: 5416 et131x_adapter_memory_free(adapter); 5417err_iounmap: 5418 iounmap(adapter->regs); 5419err_free_dev: 5420 pci_dev_put(pdev); 5421 free_netdev(netdev); 5422err_release_res: 5423 pci_release_regions(pdev); 5424err_disable: 5425 pci_disable_device(pdev); 5426 goto out; 5427} 5428 5429static DEFINE_PCI_DEVICE_TABLE(et131x_pci_table) = { 5430 { PCI_VDEVICE(ATT, ET131X_PCI_DEVICE_ID_GIG), 0UL}, 5431 { PCI_VDEVICE(ATT, ET131X_PCI_DEVICE_ID_FAST), 0UL}, 5432 {0,} 5433}; 5434MODULE_DEVICE_TABLE(pci, et131x_pci_table); 5435 5436static struct pci_driver et131x_driver = { 5437 .name = DRIVER_NAME, 5438 .id_table = et131x_pci_table, 5439 .probe = et131x_pci_setup, 5440 .remove = __devexit_p(et131x_pci_remove), 5441 .driver.pm = ET131X_PM_OPS, 5442}; 5443 5444module_pci_driver(et131x_driver);