1 /** @file
2 *
3 * Copyright (c) 2012-2014, ARM Limited. All rights reserved.
4 *
5 * This program and the accompanying materials
6 * are licensed and made available under the terms and conditions of the BSD License
7 * which accompanies this distribution. The full text of the license may be found at
8 * http://opensource.org/licenses/bsd-license.php
9 *
10 * THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,
11 * WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.
12 *
13 **/
14
15 #include "Lan9118Dxe.h"
16
17 STATIC EFI_MAC_ADDRESS mZeroMac = { { 0 } };
18
19 /**
20 This internal function reverses bits for 32bit data.
21
22 @param Value The data to be reversed.
23
24 @return Data reversed.
25
26 **/
27 UINT32
ReverseBits(UINT32 Value)28 ReverseBits (
29 UINT32 Value
30 )
31 {
32 UINTN Index;
33 UINT32 NewValue;
34
35 NewValue = 0;
36 for (Index = 0; Index < 32; Index++) {
37 if ((Value & (1 << Index)) != 0) {
38 NewValue = NewValue | (1 << (31 - Index));
39 }
40 }
41
42 return NewValue;
43 }
44
45 /*
46 ** Create Ethernet CRC
47 **
48 ** INFO USED:
49 ** 1: http://en.wikipedia.org/wiki/Cyclic_redundancy_check
50 **
51 ** 2: http://www.erg.abdn.ac.uk/~gorry/eg3567/dl-pages/crc.html
52 **
53 ** 3: http://en.wikipedia.org/wiki/Computation_of_CRC
54 */
55 UINT32
GenEtherCrc32(IN EFI_MAC_ADDRESS * Mac,IN UINT32 AddrLen)56 GenEtherCrc32 (
57 IN EFI_MAC_ADDRESS *Mac,
58 IN UINT32 AddrLen
59 )
60 {
61 INT32 Iter;
62 UINT32 Remainder;
63 UINT8 *Ptr;
64
65 Iter = 0;
66 Remainder = 0xFFFFFFFF; // 0xFFFFFFFF is standard seed for Ethernet
67
68 // Convert Mac Address to array of bytes
69 Ptr = (UINT8*)Mac;
70
71 // Generate the Crc bit-by-bit (LSB first)
72 while (AddrLen--) {
73 Remainder ^= *Ptr++;
74 for (Iter = 0;Iter < 8;Iter++) {
75 // Check if exponent is set
76 if (Remainder & 1) {
77 Remainder = (Remainder >> 1) ^ CRC_POLYNOMIAL;
78 } else {
79 Remainder = (Remainder >> 1) ^ 0;
80 }
81 }
82 }
83
84 // Reverse the bits before returning (to Big Endian)
85 //TODO: Need to be reviewed. Do we want to do a bit reverse or a byte reverse (in this case use SwapBytes32())
86 return ReverseBits (Remainder);
87 }
88
89 // Function to read from MAC indirect registers
90 UINT32
IndirectMACRead32(UINT32 Index)91 IndirectMACRead32 (
92 UINT32 Index
93 )
94 {
95 UINT32 MacCSR;
96
97 // Check index is in the range
98 ASSERT(Index <= 12);
99
100 // Wait until CSR busy bit is cleared
101 while ((MmioRead32 (LAN9118_MAC_CSR_CMD) & MAC_CSR_BUSY) == MAC_CSR_BUSY);
102
103 // Set CSR busy bit to ensure read will occur
104 // Set the R/W bit to indicate we are reading
105 // Set the index of CSR Address to access desired register
106 MacCSR = MAC_CSR_BUSY | MAC_CSR_READ | MAC_CSR_ADDR(Index);
107
108 // Write to the register
109 MmioWrite32 (LAN9118_MAC_CSR_CMD, MacCSR);
110
111 // Wait until CSR busy bit is cleared
112 while ((MmioRead32 (LAN9118_MAC_CSR_CMD) & MAC_CSR_BUSY) == MAC_CSR_BUSY);
113
114 // Now read from data register to get read value
115 return MmioRead32 (LAN9118_MAC_CSR_DATA);
116 }
117
118 // Function to write to MAC indirect registers
119 UINT32
IndirectMACWrite32(UINT32 Index,UINT32 Value)120 IndirectMACWrite32 (
121 UINT32 Index,
122 UINT32 Value
123 )
124 {
125 UINT32 ValueWritten;
126 UINT32 MacCSR;
127
128 // Check index is in the range
129 ASSERT(Index <= 12);
130
131 // Wait until CSR busy bit is cleared
132 while ((MmioRead32 (LAN9118_MAC_CSR_CMD) & MAC_CSR_BUSY) == MAC_CSR_BUSY);
133
134 // Set CSR busy bit to ensure read will occur
135 // Set the R/W bit to indicate we are writing
136 // Set the index of CSR Address to access desired register
137 MacCSR = MAC_CSR_BUSY | MAC_CSR_WRITE | MAC_CSR_ADDR(Index);
138
139 // Now write the value to the register before issuing the write command
140 ValueWritten = MmioWrite32 (LAN9118_MAC_CSR_DATA, Value);
141
142 // Write the config to the register
143 MmioWrite32 (LAN9118_MAC_CSR_CMD, MacCSR);
144
145 // Wait until CSR busy bit is cleared
146 while ((MmioRead32 (LAN9118_MAC_CSR_CMD) & MAC_CSR_BUSY) == MAC_CSR_BUSY);
147
148 return ValueWritten;
149 }
150
151 // Function to read from MII register (PHY Access)
152 UINT32
IndirectPHYRead32(UINT32 Index)153 IndirectPHYRead32 (
154 UINT32 Index
155 )
156 {
157 UINT32 ValueRead;
158 UINT32 MiiAcc;
159
160 // Check it is a valid index
161 ASSERT(Index < 31);
162
163 // Wait for busy bit to clear
164 while ((IndirectMACRead32 (INDIRECT_MAC_INDEX_MII_ACC) & MII_ACC_MII_BUSY) == MII_ACC_MII_BUSY);
165
166 // Clear the R/W bit to indicate we are reading
167 // Set the index of the MII register
168 // Set the PHY Address
169 // Set the MII busy bit to allow read
170 MiiAcc = MII_ACC_MII_READ | MII_ACC_MII_REG_INDEX(Index) | MII_ACC_PHY_VALUE | MII_ACC_MII_BUSY;
171
172 // Now write this config to register
173 IndirectMACWrite32 (INDIRECT_MAC_INDEX_MII_ACC, MiiAcc & 0xFFFF);
174
175 // Wait for busy bit to clear
176 while ((IndirectMACRead32 (INDIRECT_MAC_INDEX_MII_ACC) & MII_ACC_MII_BUSY) == MII_ACC_MII_BUSY);
177
178 // Now read the value of the register
179 ValueRead = (IndirectMACRead32 (INDIRECT_MAC_INDEX_MII_DATA) & 0xFFFF); // only lower 16 bits are valid for any PHY register
180
181 return ValueRead;
182 }
183
184
185 // Function to write to the MII register (PHY Access)
186 UINT32
IndirectPHYWrite32(UINT32 Index,UINT32 Value)187 IndirectPHYWrite32 (
188 UINT32 Index,
189 UINT32 Value
190 )
191 {
192 UINT32 MiiAcc;
193 UINT32 ValueWritten;
194
195 // Check it is a valid index
196 ASSERT(Index < 31);
197
198 // Wait for busy bit to clear
199 while ((IndirectMACRead32 (INDIRECT_MAC_INDEX_MII_ACC) & MII_ACC_MII_BUSY) == MII_ACC_MII_BUSY);
200
201 // Clear the R/W bit to indicate we are reading
202 // Set the index of the MII register
203 // Set the PHY Address
204 // Set the MII busy bit to allow read
205 MiiAcc = MII_ACC_MII_WRITE | MII_ACC_MII_REG_INDEX(Index) | MII_ACC_PHY_VALUE | MII_ACC_MII_BUSY;
206
207 // Write the desired value to the register first
208 ValueWritten = IndirectMACWrite32 (INDIRECT_MAC_INDEX_MII_DATA, (Value & 0xFFFF));
209
210 // Now write the config to register
211 IndirectMACWrite32 (INDIRECT_MAC_INDEX_MII_ACC, MiiAcc & 0xFFFF);
212
213 // Wait for operation to terminate
214 while ((IndirectMACRead32 (INDIRECT_MAC_INDEX_MII_ACC) & MII_ACC_MII_BUSY) == MII_ACC_MII_BUSY);
215
216 return ValueWritten;
217 }
218
219
220 /* ---------------- EEPROM Operations ------------------ */
221
222
223 // Function to read from EEPROM memory
224 UINT32
IndirectEEPROMRead32(UINT32 Index)225 IndirectEEPROMRead32 (
226 UINT32 Index
227 )
228 {
229 UINT32 EepromCmd;
230
231 // Set the busy bit to ensure read will occur
232 EepromCmd = E2P_EPC_BUSY | E2P_EPC_CMD_READ;
233
234 // Set the index to access desired EEPROM memory location
235 EepromCmd |= E2P_EPC_ADDRESS(Index);
236
237 // Write to Eeprom command register
238 MmioWrite32 (LAN9118_E2P_CMD, EepromCmd);
239 gBS->Stall (LAN9118_STALL);
240
241 // Wait until operation has completed
242 while (MmioRead32 (LAN9118_E2P_CMD) & E2P_EPC_BUSY);
243
244 // Check that operation didn't time out
245 if (MmioRead32 (LAN9118_E2P_CMD) & E2P_EPC_TIMEOUT) {
246 DEBUG ((EFI_D_ERROR, "EEPROM Operation Timed out: Read command on index %x\n",Index));
247 return 0;
248 }
249
250 // Wait until operation has completed
251 while (MmioRead32 (LAN9118_E2P_CMD) & E2P_EPC_BUSY);
252
253 // Finally read the value
254 return MmioRead32 (LAN9118_E2P_DATA);
255 }
256
257 // Function to write to EEPROM memory
258 UINT32
IndirectEEPROMWrite32(UINT32 Index,UINT32 Value)259 IndirectEEPROMWrite32 (
260 UINT32 Index,
261 UINT32 Value
262 )
263 {
264 UINT32 ValueWritten;
265 UINT32 EepromCmd;
266
267 ValueWritten = 0;
268
269 // Read the EEPROM Command register
270 EepromCmd = MmioRead32 (LAN9118_E2P_CMD);
271
272 // Set the busy bit to ensure read will occur
273 EepromCmd |= ((UINT32)1 << 31);
274
275 // Set the EEPROM command to write(0b011)
276 EepromCmd &= ~(7 << 28); // Clear the command first
277 EepromCmd |= (3 << 28); // Write 011
278
279 // Set the index to access desired EEPROM memory location
280 EepromCmd |= (Index & 0xF);
281
282 // Write the value to the data register first
283 ValueWritten = MmioWrite32 (LAN9118_E2P_DATA, Value);
284
285 // Write to Eeprom command register
286 MmioWrite32 (LAN9118_E2P_CMD, EepromCmd);
287 gBS->Stall (LAN9118_STALL);
288
289 // Wait until operation has completed
290 while (MmioRead32 (LAN9118_E2P_CMD) & E2P_EPC_BUSY);
291
292 // Check that operation didn't time out
293 if (MmioRead32 (LAN9118_E2P_CMD) & E2P_EPC_TIMEOUT) {
294 DEBUG ((EFI_D_ERROR, "EEPROM Operation Timed out: Write command at memloc 0x%x, with value 0x%x\n",Index, Value));
295 return 0;
296 }
297
298 // Wait until operation has completed
299 while (MmioRead32 (LAN9118_E2P_CMD) & E2P_EPC_BUSY);
300
301 return ValueWritten;
302 }
303
304 /* ---------------- General Operations ----------------- */
305
306 VOID
Lan9118SetMacAddress(EFI_MAC_ADDRESS * Mac,EFI_SIMPLE_NETWORK_PROTOCOL * Snp)307 Lan9118SetMacAddress (
308 EFI_MAC_ADDRESS *Mac,
309 EFI_SIMPLE_NETWORK_PROTOCOL *Snp
310 )
311 {
312 IndirectMACWrite32 (INDIRECT_MAC_INDEX_ADDRL,
313 (Mac->Addr[0] & 0xFF) |
314 ((Mac->Addr[1] & 0xFF) << 8) |
315 ((Mac->Addr[2] & 0xFF) << 16) |
316 ((Mac->Addr[3] & 0xFF) << 24)
317 );
318
319 IndirectMACWrite32 (INDIRECT_MAC_INDEX_ADDRH,
320 (UINT32)(Mac->Addr[4] & 0xFF) |
321 ((Mac->Addr[5] & 0xFF) << 8)
322 );
323 }
324
325 VOID
Lan9118ReadMacAddress(OUT EFI_MAC_ADDRESS * MacAddress)326 Lan9118ReadMacAddress (
327 OUT EFI_MAC_ADDRESS *MacAddress
328 )
329 {
330 UINT32 MacAddrHighValue;
331 UINT32 MacAddrLowValue;
332
333 // Read the Mac Addr high register
334 MacAddrHighValue = (IndirectMACRead32 (INDIRECT_MAC_INDEX_ADDRH) & 0xFFFF);
335 // Read the Mac Addr low register
336 MacAddrLowValue = IndirectMACRead32 (INDIRECT_MAC_INDEX_ADDRL);
337
338 SetMem (MacAddress, sizeof(*MacAddress), 0);
339 MacAddress->Addr[0] = (MacAddrLowValue & 0xFF);
340 MacAddress->Addr[1] = (MacAddrLowValue & 0xFF00) >> 8;
341 MacAddress->Addr[2] = (MacAddrLowValue & 0xFF0000) >> 16;
342 MacAddress->Addr[3] = (MacAddrLowValue & 0xFF000000) >> 24;
343 MacAddress->Addr[4] = (MacAddrHighValue & 0xFF);
344 MacAddress->Addr[5] = (MacAddrHighValue & 0xFF00) >> 8;
345 }
346
347 /*
348 * Power up the 9118 and find its MAC address.
349 *
350 * This operation can be carried out when the LAN9118 is in any power state
351 *
352 */
353 EFI_STATUS
Lan9118Initialize(IN EFI_SIMPLE_NETWORK_PROTOCOL * Snp)354 Lan9118Initialize (
355 IN EFI_SIMPLE_NETWORK_PROTOCOL *Snp
356 )
357 {
358 UINTN Timeout;
359 UINT64 DefaultMacAddress;
360
361 // Attempt to wake-up the device if it is in a lower power state
362 if (((MmioRead32 (LAN9118_PMT_CTRL) & MPTCTRL_PM_MODE_MASK) >> 12) != 0) {
363 DEBUG ((DEBUG_NET, "Waking from reduced power state.\n"));
364 MmioWrite32 (LAN9118_BYTE_TEST, 0xFFFFFFFF);
365 gBS->Stall (LAN9118_STALL);
366 }
367
368 // Check that device is active
369 Timeout = 20;
370 while ((MmioRead32 (LAN9118_PMT_CTRL) & MPTCTRL_READY) == 0 && --Timeout) {
371 gBS->Stall (LAN9118_STALL);
372 }
373 if (!Timeout) {
374 return EFI_TIMEOUT;
375 }
376
377 // Check that EEPROM isn't active
378 Timeout = 20;
379 while ((MmioRead32 (LAN9118_E2P_CMD) & E2P_EPC_BUSY) && --Timeout){
380 gBS->Stall (LAN9118_STALL);
381 }
382 if (!Timeout) {
383 return EFI_TIMEOUT;
384 }
385
386 // Check if a MAC address was loaded from EEPROM, and if it was, set it as the
387 // current address.
388 if ((MmioRead32 (LAN9118_E2P_CMD) & E2P_EPC_MAC_ADDRESS_LOADED) == 0) {
389 DEBUG ((EFI_D_ERROR, "Warning: There was an error detecting EEPROM or loading the MAC Address.\n"));
390
391 // If we had an address before (set by StationAddess), continue to use it
392 if (CompareMem (&Snp->Mode->CurrentAddress, &mZeroMac, NET_ETHER_ADDR_LEN)) {
393 Lan9118SetMacAddress (&Snp->Mode->CurrentAddress, Snp);
394 } else {
395 // If there are no cached addresses, then fall back to a default
396 DEBUG ((EFI_D_WARN, "Warning: using driver-default MAC address\n"));
397 DefaultMacAddress = FixedPcdGet64 (PcdLan9118DefaultMacAddress);
398 Lan9118SetMacAddress((EFI_MAC_ADDRESS *) &DefaultMacAddress, Snp);
399 CopyMem (&Snp->Mode->CurrentAddress, &DefaultMacAddress, NET_ETHER_ADDR_LEN);
400 }
401 } else {
402 // Store the MAC address that was loaded from EEPROM
403 Lan9118ReadMacAddress (&Snp->Mode->CurrentAddress);
404 CopyMem (&Snp->Mode->PermanentAddress, &Snp->Mode->CurrentAddress, NET_ETHER_ADDR_LEN);
405 }
406
407 // Clear and acknowledge interrupts
408 MmioWrite32 (LAN9118_INT_EN, 0);
409 MmioWrite32 (LAN9118_IRQ_CFG, 0);
410 MmioWrite32 (LAN9118_INT_STS, 0xFFFFFFFF);
411
412 // Do self tests here?
413
414 return EFI_SUCCESS;
415 }
416
417
418 // Perform software reset on the LAN9118
419 // Return 0 on success, -1 on error
420 EFI_STATUS
SoftReset(UINT32 Flags,EFI_SIMPLE_NETWORK_PROTOCOL * Snp)421 SoftReset (
422 UINT32 Flags,
423 EFI_SIMPLE_NETWORK_PROTOCOL *Snp
424 )
425 {
426 UINT32 HwConf;
427 UINT32 ResetTime;
428
429 // Initialize variable
430 ResetTime = 0;
431
432 // Stop Rx and Tx
433 StopTx (STOP_TX_MAC | STOP_TX_CFG | STOP_TX_CLEAR, Snp);
434 StopRx (STOP_RX_CLEAR, Snp); // Clear receiver FIFO
435
436 // Issue the reset
437 HwConf = MmioRead32 (LAN9118_HW_CFG);
438 HwConf |= 1;
439
440 // Set the Must Be One (MBO) bit
441 if (((HwConf & HWCFG_MBO) >> 20) == 0) {
442 HwConf |= HWCFG_MBO;
443 }
444
445 // Check that EEPROM isn't active
446 while (MmioRead32 (LAN9118_E2P_CMD) & E2P_EPC_BUSY);
447
448 // Write the configuration
449 MmioWrite32 (LAN9118_HW_CFG, HwConf);
450 gBS->Stall (LAN9118_STALL);
451
452 // Wait for reset to complete
453 while (MmioRead32 (LAN9118_HW_CFG) & HWCFG_SRST) {
454
455 gBS->Stall (LAN9118_STALL);
456 ResetTime += 1;
457
458 // If time taken exceeds 100us, then there was an error condition
459 if (ResetTime > 1000) {
460 Snp->Mode->State = EfiSimpleNetworkStopped;
461 return EFI_TIMEOUT;
462 }
463 }
464
465 // Check that EEPROM isn't active
466 while (MmioRead32 (LAN9118_E2P_CMD) & E2P_EPC_BUSY);
467
468 // TODO we probably need to re-set the mac address here.
469
470 // Clear and acknowledge all interrupts
471 if (Flags & SOFT_RESET_CLEAR_INT) {
472 MmioWrite32 (LAN9118_INT_EN, 0);
473 MmioWrite32 (LAN9118_IRQ_CFG, 0);
474 MmioWrite32 (LAN9118_INT_STS, 0xFFFFFFFF);
475 }
476
477 // Do self tests here?
478 if (Flags & SOFT_RESET_SELF_TEST) {
479
480 }
481
482 return EFI_SUCCESS;
483 }
484
485
486 // Perform PHY software reset
487 EFI_STATUS
PhySoftReset(UINT32 Flags,EFI_SIMPLE_NETWORK_PROTOCOL * Snp)488 PhySoftReset (
489 UINT32 Flags,
490 EFI_SIMPLE_NETWORK_PROTOCOL *Snp
491 )
492 {
493 UINT32 PmtCtrl = 0;
494
495 // PMT PHY reset takes precedence over BCR
496 if (Flags & PHY_RESET_PMT) {
497 PmtCtrl = MmioRead32 (LAN9118_PMT_CTRL);
498 PmtCtrl |= MPTCTRL_PHY_RST;
499 MmioWrite32 (LAN9118_PMT_CTRL,PmtCtrl);
500
501 // Wait for completion
502 while (MmioRead32 (LAN9118_PMT_CTRL) & MPTCTRL_PHY_RST) {
503 gBS->Stall (LAN9118_STALL);
504 }
505 // PHY Basic Control Register reset
506 } else if (Flags & PHY_RESET_BCR) {
507 IndirectPHYWrite32 (PHY_INDEX_BASIC_CTRL, PHYCR_RESET);
508
509 // Wait for completion
510 while (IndirectPHYRead32 (PHY_INDEX_BASIC_CTRL) & PHYCR_RESET) {
511 gBS->Stall (LAN9118_STALL);
512 }
513 }
514
515 // Clear and acknowledge all interrupts
516 if (Flags & PHY_SOFT_RESET_CLEAR_INT) {
517 MmioWrite32 (LAN9118_INT_EN, 0);
518 MmioWrite32 (LAN9118_IRQ_CFG, 0);
519 MmioWrite32 (LAN9118_INT_STS, 0xFFFFFFFF);
520 }
521
522 return EFI_SUCCESS;
523 }
524
525
526 // Configure hardware for LAN9118
527 EFI_STATUS
ConfigureHardware(UINT32 Flags,EFI_SIMPLE_NETWORK_PROTOCOL * Snp)528 ConfigureHardware (
529 UINT32 Flags,
530 EFI_SIMPLE_NETWORK_PROTOCOL *Snp
531 )
532 {
533 UINT32 GpioConf;
534
535 // Check if we want to use LEDs on GPIO
536 if (Flags & HW_CONF_USE_LEDS) {
537 GpioConf = MmioRead32 (LAN9118_GPIO_CFG);
538
539 // Enable GPIO as LEDs and Config as Push-Pull driver
540 GpioConf |= GPIO_GPIO0_PUSH_PULL | GPIO_GPIO1_PUSH_PULL | GPIO_GPIO2_PUSH_PULL |
541 GPIO_LED1_ENABLE | GPIO_LED2_ENABLE | GPIO_LED3_ENABLE;
542
543 // Write the configuration
544 MmioWrite32 (LAN9118_GPIO_CFG, GpioConf);
545 gBS->Stall (LAN9118_STALL);
546 }
547
548 return EFI_SUCCESS;
549 }
550
551 // Configure flow control
552 EFI_STATUS
ConfigureFlow(UINT32 Flags,UINT32 HighTrig,UINT32 LowTrig,UINT32 BPDuration,EFI_SIMPLE_NETWORK_PROTOCOL * Snp)553 ConfigureFlow (
554 UINT32 Flags,
555 UINT32 HighTrig,
556 UINT32 LowTrig,
557 UINT32 BPDuration,
558 EFI_SIMPLE_NETWORK_PROTOCOL *Snp
559 )
560 {
561 return EFI_SUCCESS;
562 }
563
564 // Do auto-negotiation
565 EFI_STATUS
AutoNegotiate(UINT32 Flags,EFI_SIMPLE_NETWORK_PROTOCOL * Snp)566 AutoNegotiate (
567 UINT32 Flags,
568 EFI_SIMPLE_NETWORK_PROTOCOL *Snp
569 )
570 {
571 UINT32 PhyControl;
572 UINT32 PhyStatus;
573 UINT32 Features;
574 UINT32 TimeOut;
575
576 // First check that auto-negotiation is supported
577 PhyStatus = IndirectPHYRead32 (PHY_INDEX_BASIC_STATUS);
578 if ((PhyStatus & PHYSTS_AUTO_CAP) == 0) {
579 DEBUG ((EFI_D_ERROR, "Auto-negotiation not supported.\n"));
580 return EFI_DEVICE_ERROR;
581 }
582
583 // Check that link is up first
584 if ((PhyStatus & PHYSTS_LINK_STS) == 0) {
585 // Wait until it is up or until Time Out
586 TimeOut = 2000;
587 while ((IndirectPHYRead32 (PHY_INDEX_BASIC_STATUS) & PHYSTS_LINK_STS) == 0) {
588 gBS->Stall (LAN9118_STALL);
589 TimeOut--;
590 if (!TimeOut) {
591 DEBUG ((EFI_D_ERROR, "Link timeout in auto-negotiation.\n"));
592 return EFI_TIMEOUT;
593 }
594 }
595 }
596
597 // Configure features to advertise
598 Features = IndirectPHYRead32 (PHY_INDEX_AUTO_NEG_ADVERT);
599
600 if ((Flags & AUTO_NEGOTIATE_ADVERTISE_ALL) > 0) {
601 // Link speed capabilities
602 Features |= (PHYANA_10BASET | PHYANA_10BASETFD | PHYANA_100BASETX | PHYANA_100BASETXFD);
603
604 // Pause frame capabilities
605 Features &= ~(PHYANA_PAUSE_OP_MASK);
606 Features |= 3 << 10;
607 }
608
609 // Write the features
610 IndirectPHYWrite32 (PHY_INDEX_AUTO_NEG_ADVERT, Features);
611
612 // Read control register
613 PhyControl = IndirectPHYRead32 (PHY_INDEX_BASIC_CTRL);
614
615 // Enable Auto-Negotiation
616 if ((PhyControl & PHYCR_AUTO_EN) == 0) {
617 PhyControl |= PHYCR_AUTO_EN;
618 }
619
620 // Restart auto-negotiation
621 PhyControl |= PHYCR_RST_AUTO;
622
623 // Enable collision test if required to do so
624 if (Flags & AUTO_NEGOTIATE_COLLISION_TEST) {
625 PhyControl |= PHYCR_COLL_TEST;
626 } else {
627 PhyControl &= ~ PHYCR_COLL_TEST;
628 }
629
630 // Write this configuration
631 IndirectPHYWrite32 (PHY_INDEX_BASIC_CTRL, PhyControl);
632
633 // Wait until process has completed
634 while ((IndirectPHYRead32 (PHY_INDEX_BASIC_STATUS) & PHYSTS_AUTO_COMP) == 0);
635
636 return EFI_SUCCESS;
637 }
638
639 // Check the Link Status and take appropriate action
640 EFI_STATUS
CheckLinkStatus(UINT32 Flags,EFI_SIMPLE_NETWORK_PROTOCOL * Snp)641 CheckLinkStatus (
642 UINT32 Flags,
643 EFI_SIMPLE_NETWORK_PROTOCOL *Snp
644 )
645 {
646 // Get the PHY Status
647 UINT32 PhyBStatus = IndirectPHYRead32 (PHY_INDEX_BASIC_STATUS);
648
649 if (PhyBStatus & PHYSTS_LINK_STS) {
650 return EFI_SUCCESS;
651 } else {
652 return EFI_DEVICE_ERROR;
653 }
654 }
655
656 // Stop the transmitter
657 EFI_STATUS
StopTx(UINT32 Flags,EFI_SIMPLE_NETWORK_PROTOCOL * Snp)658 StopTx (
659 UINT32 Flags,
660 EFI_SIMPLE_NETWORK_PROTOCOL *Snp
661 )
662 {
663 UINT32 MacCsr;
664 UINT32 TxCfg;
665
666 MacCsr = 0;
667 TxCfg = 0;
668
669 // Check if we want to clear tx
670 if (Flags & STOP_TX_CLEAR) {
671 TxCfg = MmioRead32 (LAN9118_TX_CFG);
672 TxCfg |= TXCFG_TXS_DUMP | TXCFG_TXD_DUMP;
673 MmioWrite32 (LAN9118_TX_CFG, TxCfg);
674 gBS->Stall (LAN9118_STALL);
675 }
676
677 // Check if already stopped
678 if (Flags & STOP_TX_MAC) {
679 MacCsr = IndirectMACRead32 (INDIRECT_MAC_INDEX_CR);
680
681 if (MacCsr & MACCR_TX_EN) {
682 MacCsr &= ~MACCR_TX_EN;
683 IndirectMACWrite32 (INDIRECT_MAC_INDEX_CR, MacCsr);
684 }
685 }
686
687 if (Flags & STOP_TX_CFG) {
688 TxCfg = MmioRead32 (LAN9118_TX_CFG);
689
690 if (TxCfg & TXCFG_TX_ON) {
691 TxCfg |= TXCFG_STOP_TX;
692 MmioWrite32 (LAN9118_TX_CFG, TxCfg);
693 gBS->Stall (LAN9118_STALL);
694
695 // Wait for Tx to finish transmitting
696 while (MmioRead32 (LAN9118_TX_CFG) & TXCFG_STOP_TX);
697 }
698 }
699
700 return EFI_SUCCESS;
701 }
702
703 // Stop the receiver
704 EFI_STATUS
StopRx(UINT32 Flags,EFI_SIMPLE_NETWORK_PROTOCOL * Snp)705 StopRx (
706 UINT32 Flags,
707 EFI_SIMPLE_NETWORK_PROTOCOL *Snp
708 )
709 {
710 UINT32 MacCsr;
711 UINT32 RxCfg;
712
713 RxCfg = 0;
714
715 // Check if already stopped
716 MacCsr = IndirectMACRead32 (INDIRECT_MAC_INDEX_CR);
717
718 if (MacCsr & MACCR_RX_EN) {
719 MacCsr &= ~ MACCR_RX_EN;
720 IndirectMACWrite32 (INDIRECT_MAC_INDEX_CR, MacCsr);
721 }
722
723 // Check if we want to clear receiver FIFOs
724 if (Flags & STOP_RX_CLEAR) {
725 RxCfg = MmioRead32 (LAN9118_RX_CFG);
726 RxCfg |= RXCFG_RX_DUMP;
727 MmioWrite32 (LAN9118_RX_CFG, RxCfg);
728 gBS->Stall (LAN9118_STALL);
729
730 while (MmioRead32 (LAN9118_RX_CFG) & RXCFG_RX_DUMP);
731 }
732
733 return EFI_SUCCESS;
734 }
735
736 // Start the transmitter
737 EFI_STATUS
StartTx(UINT32 Flags,EFI_SIMPLE_NETWORK_PROTOCOL * Snp)738 StartTx (
739 UINT32 Flags,
740 EFI_SIMPLE_NETWORK_PROTOCOL *Snp
741 )
742 {
743 UINT32 MacCsr;
744 UINT32 TxCfg;
745
746 MacCsr = 0;
747 TxCfg = 0;
748
749 // Check if we want to clear tx
750 if (Flags & START_TX_CLEAR) {
751 TxCfg = MmioRead32 (LAN9118_TX_CFG);
752 TxCfg |= TXCFG_TXS_DUMP | TXCFG_TXD_DUMP;
753 MmioWrite32 (LAN9118_TX_CFG, TxCfg);
754 gBS->Stall (LAN9118_STALL);
755 }
756
757 // Check if tx was started from MAC and enable if not
758 if (Flags & START_TX_MAC) {
759 MacCsr = IndirectMACRead32 (INDIRECT_MAC_INDEX_CR);
760 gBS->Stall (LAN9118_STALL);
761 if ((MacCsr & MACCR_TX_EN) == 0) {
762 MacCsr |= MACCR_TX_EN;
763 IndirectMACWrite32 (INDIRECT_MAC_INDEX_CR, MacCsr);
764 gBS->Stall (LAN9118_STALL);
765 }
766 }
767
768 // Check if tx was started from TX_CFG and enable if not
769 if (Flags & START_TX_CFG) {
770 TxCfg = MmioRead32 (LAN9118_TX_CFG);
771 gBS->Stall (LAN9118_STALL);
772 if ((TxCfg & TXCFG_TX_ON) == 0) {
773 TxCfg |= TXCFG_TX_ON;
774 MmioWrite32 (LAN9118_TX_CFG, TxCfg);
775 gBS->Stall (LAN9118_STALL);
776 }
777 }
778
779 // Set the tx data trigger level
780
781 return EFI_SUCCESS;
782 }
783
784 // Start the receiver
785 EFI_STATUS
StartRx(UINT32 Flags,EFI_SIMPLE_NETWORK_PROTOCOL * Snp)786 StartRx (
787 UINT32 Flags,
788 EFI_SIMPLE_NETWORK_PROTOCOL *Snp
789 )
790 {
791 UINT32 MacCsr;
792 UINT32 RxCfg;
793
794 RxCfg = 0;
795
796 // Check if already started
797 MacCsr = IndirectMACRead32 (INDIRECT_MAC_INDEX_CR);
798
799 if ((MacCsr & MACCR_RX_EN) == 0) {
800 // Check if we want to clear receiver FIFOs before starting
801 if (Flags & START_RX_CLEAR) {
802 RxCfg = MmioRead32 (LAN9118_RX_CFG);
803 RxCfg |= RXCFG_RX_DUMP;
804 MmioWrite32 (LAN9118_RX_CFG, RxCfg);
805 gBS->Stall (LAN9118_STALL);
806
807 while (MmioRead32 (LAN9118_RX_CFG) & RXCFG_RX_DUMP);
808 }
809
810 MacCsr |= MACCR_RX_EN;
811 IndirectMACWrite32 (INDIRECT_MAC_INDEX_CR, MacCsr);
812 gBS->Stall (LAN9118_STALL);
813 }
814
815 return EFI_SUCCESS;
816 }
817
818 // Check Tx Data available space
819 UINT32
TxDataFreeSpace(UINT32 Flags,EFI_SIMPLE_NETWORK_PROTOCOL * Snp)820 TxDataFreeSpace (
821 UINT32 Flags,
822 EFI_SIMPLE_NETWORK_PROTOCOL *Snp
823 )
824 {
825 UINT32 TxInf;
826 UINT32 FreeSpace;
827
828 // Get the amount of free space from information register
829 TxInf = MmioRead32 (LAN9118_TX_FIFO_INF);
830 FreeSpace = (TxInf & TXFIFOINF_TDFREE_MASK);
831
832 return FreeSpace; // Value in bytes
833 }
834
835 // Check Tx Status used space
836 UINT32
TxStatusUsedSpace(UINT32 Flags,EFI_SIMPLE_NETWORK_PROTOCOL * Snp)837 TxStatusUsedSpace (
838 UINT32 Flags,
839 EFI_SIMPLE_NETWORK_PROTOCOL *Snp
840 )
841 {
842 UINT32 TxInf;
843 UINT32 UsedSpace;
844
845 // Get the amount of used space from information register
846 TxInf = MmioRead32 (LAN9118_TX_FIFO_INF);
847 UsedSpace = (TxInf & TXFIFOINF_TXSUSED_MASK) >> 16;
848
849 return UsedSpace << 2; // Value in bytes
850 }
851
852 // Check Rx Data used space
853 UINT32
RxDataUsedSpace(UINT32 Flags,EFI_SIMPLE_NETWORK_PROTOCOL * Snp)854 RxDataUsedSpace (
855 UINT32 Flags,
856 EFI_SIMPLE_NETWORK_PROTOCOL *Snp
857 )
858 {
859 UINT32 RxInf;
860 UINT32 UsedSpace;
861
862 // Get the amount of used space from information register
863 RxInf = MmioRead32 (LAN9118_RX_FIFO_INF);
864 UsedSpace = (RxInf & RXFIFOINF_RXDUSED_MASK);
865
866 return UsedSpace; // Value in bytes (rounded up to nearest DWORD)
867 }
868
869 // Check Rx Status used space
870 UINT32
RxStatusUsedSpace(UINT32 Flags,EFI_SIMPLE_NETWORK_PROTOCOL * Snp)871 RxStatusUsedSpace (
872 UINT32 Flags,
873 EFI_SIMPLE_NETWORK_PROTOCOL *Snp
874 )
875 {
876 UINT32 RxInf;
877 UINT32 UsedSpace;
878
879 // Get the amount of used space from information register
880 RxInf = MmioRead32 (LAN9118_RX_FIFO_INF);
881 UsedSpace = (RxInf & RXFIFOINF_RXSUSED_MASK) >> 16;
882
883 return UsedSpace << 2; // Value in bytes
884 }
885
886
887 // Change the allocation of FIFOs
888 EFI_STATUS
ChangeFifoAllocation(IN UINT32 Flags,IN OUT UINTN * TxDataSize OPTIONAL,IN OUT UINTN * RxDataSize OPTIONAL,IN OUT UINT32 * TxStatusSize OPTIONAL,IN OUT UINT32 * RxStatusSize OPTIONAL,IN OUT EFI_SIMPLE_NETWORK_PROTOCOL * Snp)889 ChangeFifoAllocation (
890 IN UINT32 Flags,
891 IN OUT UINTN *TxDataSize OPTIONAL,
892 IN OUT UINTN *RxDataSize OPTIONAL,
893 IN OUT UINT32 *TxStatusSize OPTIONAL,
894 IN OUT UINT32 *RxStatusSize OPTIONAL,
895 IN OUT EFI_SIMPLE_NETWORK_PROTOCOL *Snp
896 )
897 {
898 UINT32 HwConf;
899 UINT32 TxFifoOption;
900
901 // Check that desired sizes don't exceed limits
902 if (*TxDataSize > TX_FIFO_MAX_SIZE)
903 return EFI_INVALID_PARAMETER;
904
905 #if defined(RX_FIFO_MIN_SIZE) && defined(RX_FIFO_MAX_SIZE)
906 if (*RxDataSize > RX_FIFO_MAX_SIZE) {
907 return EFI_INVALID_PARAMETER;
908 }
909 #endif
910
911 if (Flags & ALLOC_USE_DEFAULT) {
912 return EFI_SUCCESS;
913 }
914
915 // If we use the FIFOs (always use this first)
916 if (Flags & ALLOC_USE_FIFOS) {
917 // Read the current value of allocation
918 HwConf = MmioRead32 (LAN9118_HW_CFG);
919 TxFifoOption = (HwConf >> 16) & 0xF;
920
921 // Choose the correct size (always use larger than requested if possible)
922 if (*TxDataSize < TX_FIFO_MIN_SIZE) {
923 *TxDataSize = TX_FIFO_MIN_SIZE;
924 *RxDataSize = 13440;
925 *RxStatusSize = 896;
926 TxFifoOption = 2;
927 } else if ((*TxDataSize > TX_FIFO_MIN_SIZE) && (*TxDataSize <= 2560)) {
928 *TxDataSize = 2560;
929 *RxDataSize = 12480;
930 *RxStatusSize = 832;
931 TxFifoOption = 3;
932 } else if ((*TxDataSize > 2560) && (*TxDataSize <= 3584)) {
933 *TxDataSize = 3584;
934 *RxDataSize = 11520;
935 *RxStatusSize = 768;
936 TxFifoOption = 4;
937 } else if ((*TxDataSize > 3584) && (*TxDataSize <= 4608)) { // default option
938 *TxDataSize = 4608;
939 *RxDataSize = 10560;
940 *RxStatusSize = 704;
941 TxFifoOption = 5;
942 } else if ((*TxDataSize > 4608) && (*TxDataSize <= 5632)) {
943 *TxDataSize = 5632;
944 *RxDataSize = 9600;
945 *RxStatusSize = 640;
946 TxFifoOption = 6;
947 } else if ((*TxDataSize > 5632) && (*TxDataSize <= 6656)) {
948 *TxDataSize = 6656;
949 *RxDataSize = 8640;
950 *RxStatusSize = 576;
951 TxFifoOption = 7;
952 } else if ((*TxDataSize > 6656) && (*TxDataSize <= 7680)) {
953 *TxDataSize = 7680;
954 *RxDataSize = 7680;
955 *RxStatusSize = 512;
956 TxFifoOption = 8;
957 } else if ((*TxDataSize > 7680) && (*TxDataSize <= 8704)) {
958 *TxDataSize = 8704;
959 *RxDataSize = 6720;
960 *RxStatusSize = 448;
961 TxFifoOption = 9;
962 } else if ((*TxDataSize > 8704) && (*TxDataSize <= 9728)) {
963 *TxDataSize = 9728;
964 *RxDataSize = 5760;
965 *RxStatusSize = 384;
966 TxFifoOption = 10;
967 } else if ((*TxDataSize > 9728) && (*TxDataSize <= 10752)) {
968 *TxDataSize = 10752;
969 *RxDataSize = 4800;
970 *RxStatusSize = 320;
971 TxFifoOption = 11;
972 } else if ((*TxDataSize > 10752) && (*TxDataSize <= 11776)) {
973 *TxDataSize = 11776;
974 *RxDataSize = 3840;
975 *RxStatusSize = 256;
976 TxFifoOption = 12;
977 } else if ((*TxDataSize > 11776) && (*TxDataSize <= 12800)) {
978 *TxDataSize = 12800;
979 *RxDataSize = 2880;
980 *RxStatusSize = 192;
981 TxFifoOption = 13;
982 } else if ((*TxDataSize > 12800) && (*TxDataSize <= 13824)) {
983 *TxDataSize = 13824;
984 *RxDataSize = 1920;
985 *RxStatusSize = 128;
986 TxFifoOption = 14;
987 }
988 } else {
989 ASSERT(0); // Untested code path
990 HwConf = 0;
991 TxFifoOption = 0;
992 }
993
994 // Do we need DMA?
995 if (Flags & ALLOC_USE_DMA) {
996 return EFI_UNSUPPORTED; // Unsupported as of now
997 }
998 // Clear and assign the new size option
999 HwConf &= ~(0xF0000);
1000 HwConf |= ((TxFifoOption & 0xF) << 16);
1001 MmioWrite32 (LAN9118_HW_CFG, HwConf);
1002 gBS->Stall (LAN9118_STALL);
1003
1004 return EFI_SUCCESS;
1005 }
1006