1 /** @file
2 Network library.
3
4 Copyright (c) 2005 - 2016, Intel Corporation. All rights reserved.<BR>
5 (C) Copyright 2015 Hewlett Packard Enterprise Development LP<BR>
6 This program and the accompanying materials
7 are licensed and made available under the terms and conditions of the BSD License
8 which accompanies this distribution. The full text of the license may be found at
9 http://opensource.org/licenses/bsd-license.php
10
11 THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,
12 WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.
13 **/
14
15 #include <Uefi.h>
16
17 #include <IndustryStandard/SmBios.h>
18
19 #include <Protocol/DriverBinding.h>
20 #include <Protocol/ServiceBinding.h>
21 #include <Protocol/SimpleNetwork.h>
22 #include <Protocol/ManagedNetwork.h>
23 #include <Protocol/Ip4Config2.h>
24 #include <Protocol/ComponentName.h>
25 #include <Protocol/ComponentName2.h>
26
27 #include <Guid/SmBios.h>
28
29 #include <Library/NetLib.h>
30 #include <Library/BaseLib.h>
31 #include <Library/DebugLib.h>
32 #include <Library/BaseMemoryLib.h>
33 #include <Library/UefiBootServicesTableLib.h>
34 #include <Library/UefiRuntimeServicesTableLib.h>
35 #include <Library/MemoryAllocationLib.h>
36 #include <Library/DevicePathLib.h>
37 #include <Library/PrintLib.h>
38 #include <Library/UefiLib.h>
39
40 #define NIC_ITEM_CONFIG_SIZE sizeof (NIC_IP4_CONFIG_INFO) + sizeof (EFI_IP4_ROUTE_TABLE) * MAX_IP4_CONFIG_IN_VARIABLE
41 #define DEFAULT_ZERO_START ((UINTN) ~0)
42
43 //
44 // All the supported IP4 maskes in host byte order.
45 //
46 GLOBAL_REMOVE_IF_UNREFERENCED IP4_ADDR gIp4AllMasks[IP4_MASK_NUM] = {
47 0x00000000,
48 0x80000000,
49 0xC0000000,
50 0xE0000000,
51 0xF0000000,
52 0xF8000000,
53 0xFC000000,
54 0xFE000000,
55
56 0xFF000000,
57 0xFF800000,
58 0xFFC00000,
59 0xFFE00000,
60 0xFFF00000,
61 0xFFF80000,
62 0xFFFC0000,
63 0xFFFE0000,
64
65 0xFFFF0000,
66 0xFFFF8000,
67 0xFFFFC000,
68 0xFFFFE000,
69 0xFFFFF000,
70 0xFFFFF800,
71 0xFFFFFC00,
72 0xFFFFFE00,
73
74 0xFFFFFF00,
75 0xFFFFFF80,
76 0xFFFFFFC0,
77 0xFFFFFFE0,
78 0xFFFFFFF0,
79 0xFFFFFFF8,
80 0xFFFFFFFC,
81 0xFFFFFFFE,
82 0xFFFFFFFF,
83 };
84
85 GLOBAL_REMOVE_IF_UNREFERENCED EFI_IPv4_ADDRESS mZeroIp4Addr = {{0, 0, 0, 0}};
86
87 //
88 // Any error level digitally larger than mNetDebugLevelMax
89 // will be silently discarded.
90 //
91 GLOBAL_REMOVE_IF_UNREFERENCED UINTN mNetDebugLevelMax = NETDEBUG_LEVEL_ERROR;
92 GLOBAL_REMOVE_IF_UNREFERENCED UINT32 mSyslogPacketSeq = 0xDEADBEEF;
93
94 //
95 // You can change mSyslogDstMac mSyslogDstIp and mSyslogSrcIp
96 // here to direct the syslog packets to the syslog deamon. The
97 // default is broadcast to both the ethernet and IP.
98 //
99 GLOBAL_REMOVE_IF_UNREFERENCED UINT8 mSyslogDstMac[NET_ETHER_ADDR_LEN] = {0xff, 0xff, 0xff, 0xff, 0xff, 0xff};
100 GLOBAL_REMOVE_IF_UNREFERENCED UINT32 mSyslogDstIp = 0xffffffff;
101 GLOBAL_REMOVE_IF_UNREFERENCED UINT32 mSyslogSrcIp = 0;
102
103 GLOBAL_REMOVE_IF_UNREFERENCED CHAR8 *mMonthName[] = {
104 "Jan",
105 "Feb",
106 "Mar",
107 "Apr",
108 "May",
109 "Jun",
110 "Jul",
111 "Aug",
112 "Sep",
113 "Oct",
114 "Nov",
115 "Dec"
116 };
117
118 //
119 // VLAN device path node template
120 //
121 GLOBAL_REMOVE_IF_UNREFERENCED VLAN_DEVICE_PATH mNetVlanDevicePathTemplate = {
122 {
123 MESSAGING_DEVICE_PATH,
124 MSG_VLAN_DP,
125 {
126 (UINT8) (sizeof (VLAN_DEVICE_PATH)),
127 (UINT8) ((sizeof (VLAN_DEVICE_PATH)) >> 8)
128 }
129 },
130 0
131 };
132
133 /**
134 Locate the handles that support SNP, then open one of them
135 to send the syslog packets. The caller isn't required to close
136 the SNP after use because the SNP is opened by HandleProtocol.
137
138 @return The point to SNP if one is properly openned. Otherwise NULL
139
140 **/
141 EFI_SIMPLE_NETWORK_PROTOCOL *
SyslogLocateSnp(VOID)142 SyslogLocateSnp (
143 VOID
144 )
145 {
146 EFI_SIMPLE_NETWORK_PROTOCOL *Snp;
147 EFI_STATUS Status;
148 EFI_HANDLE *Handles;
149 UINTN HandleCount;
150 UINTN Index;
151
152 //
153 // Locate the handles which has SNP installed.
154 //
155 Handles = NULL;
156 Status = gBS->LocateHandleBuffer (
157 ByProtocol,
158 &gEfiSimpleNetworkProtocolGuid,
159 NULL,
160 &HandleCount,
161 &Handles
162 );
163
164 if (EFI_ERROR (Status) || (HandleCount == 0)) {
165 return NULL;
166 }
167
168 //
169 // Try to open one of the ethernet SNP protocol to send packet
170 //
171 Snp = NULL;
172
173 for (Index = 0; Index < HandleCount; Index++) {
174 Status = gBS->HandleProtocol (
175 Handles[Index],
176 &gEfiSimpleNetworkProtocolGuid,
177 (VOID **) &Snp
178 );
179
180 if ((Status == EFI_SUCCESS) && (Snp != NULL) &&
181 (Snp->Mode->IfType == NET_IFTYPE_ETHERNET) &&
182 (Snp->Mode->MaxPacketSize >= NET_SYSLOG_PACKET_LEN)) {
183
184 break;
185 }
186
187 Snp = NULL;
188 }
189
190 FreePool (Handles);
191 return Snp;
192 }
193
194 /**
195 Transmit a syslog packet synchronously through SNP. The Packet
196 already has the ethernet header prepended. This function should
197 fill in the source MAC because it will try to locate a SNP each
198 time it is called to avoid the problem if SNP is unloaded.
199 This code snip is copied from MNP.
200
201 @param[in] Packet The Syslog packet
202 @param[in] Length The length of the packet
203
204 @retval EFI_DEVICE_ERROR Failed to locate a usable SNP protocol
205 @retval EFI_TIMEOUT Timeout happened to send the packet.
206 @retval EFI_SUCCESS Packet is sent.
207
208 **/
209 EFI_STATUS
SyslogSendPacket(IN CHAR8 * Packet,IN UINT32 Length)210 SyslogSendPacket (
211 IN CHAR8 *Packet,
212 IN UINT32 Length
213 )
214 {
215 EFI_SIMPLE_NETWORK_PROTOCOL *Snp;
216 ETHER_HEAD *Ether;
217 EFI_STATUS Status;
218 EFI_EVENT TimeoutEvent;
219 UINT8 *TxBuf;
220
221 Snp = SyslogLocateSnp ();
222
223 if (Snp == NULL) {
224 return EFI_DEVICE_ERROR;
225 }
226
227 Ether = (ETHER_HEAD *) Packet;
228 CopyMem (Ether->SrcMac, Snp->Mode->CurrentAddress.Addr, NET_ETHER_ADDR_LEN);
229
230 //
231 // Start the timeout event.
232 //
233 Status = gBS->CreateEvent (
234 EVT_TIMER,
235 TPL_NOTIFY,
236 NULL,
237 NULL,
238 &TimeoutEvent
239 );
240
241 if (EFI_ERROR (Status)) {
242 return Status;
243 }
244
245 Status = gBS->SetTimer (TimeoutEvent, TimerRelative, NET_SYSLOG_TX_TIMEOUT);
246
247 if (EFI_ERROR (Status)) {
248 goto ON_EXIT;
249 }
250
251 for (;;) {
252 //
253 // Transmit the packet through SNP.
254 //
255 Status = Snp->Transmit (Snp, 0, Length, Packet, NULL, NULL, NULL);
256
257 if ((Status != EFI_SUCCESS) && (Status != EFI_NOT_READY)) {
258 Status = EFI_DEVICE_ERROR;
259 break;
260 }
261
262 //
263 // If Status is EFI_SUCCESS, the packet is put in the transmit queue.
264 // if Status is EFI_NOT_READY, the transmit engine of the network
265 // interface is busy. Both need to sync SNP.
266 //
267 TxBuf = NULL;
268
269 do {
270 //
271 // Get the recycled transmit buffer status.
272 //
273 Snp->GetStatus (Snp, NULL, (VOID **) &TxBuf);
274
275 if (!EFI_ERROR (gBS->CheckEvent (TimeoutEvent))) {
276 Status = EFI_TIMEOUT;
277 break;
278 }
279
280 } while (TxBuf == NULL);
281
282 if ((Status == EFI_SUCCESS) || (Status == EFI_TIMEOUT)) {
283 break;
284 }
285
286 //
287 // Status is EFI_NOT_READY. Restart the timer event and
288 // call Snp->Transmit again.
289 //
290 gBS->SetTimer (TimeoutEvent, TimerRelative, NET_SYSLOG_TX_TIMEOUT);
291 }
292
293 gBS->SetTimer (TimeoutEvent, TimerCancel, 0);
294
295 ON_EXIT:
296 gBS->CloseEvent (TimeoutEvent);
297 return Status;
298 }
299
300 /**
301 Build a syslog packet, including the Ethernet/Ip/Udp headers
302 and user's message.
303
304 @param[in] Level Syslog severity level
305 @param[in] Module The module that generates the log
306 @param[in] File The file that contains the current log
307 @param[in] Line The line of code in the File that contains the current log
308 @param[in] Message The log message
309 @param[in] BufLen The lenght of the Buf
310 @param[out] Buf The buffer to put the packet data
311
312 @return The length of the syslog packet built.
313
314 **/
315 UINT32
SyslogBuildPacket(IN UINT32 Level,IN UINT8 * Module,IN UINT8 * File,IN UINT32 Line,IN UINT8 * Message,IN UINT32 BufLen,OUT CHAR8 * Buf)316 SyslogBuildPacket (
317 IN UINT32 Level,
318 IN UINT8 *Module,
319 IN UINT8 *File,
320 IN UINT32 Line,
321 IN UINT8 *Message,
322 IN UINT32 BufLen,
323 OUT CHAR8 *Buf
324 )
325 {
326 ETHER_HEAD *Ether;
327 IP4_HEAD *Ip4;
328 EFI_UDP_HEADER *Udp4;
329 EFI_TIME Time;
330 UINT32 Pri;
331 UINT32 Len;
332
333 //
334 // Fill in the Ethernet header. Leave alone the source MAC.
335 // SyslogSendPacket will fill in the address for us.
336 //
337 Ether = (ETHER_HEAD *) Buf;
338 CopyMem (Ether->DstMac, mSyslogDstMac, NET_ETHER_ADDR_LEN);
339 ZeroMem (Ether->SrcMac, NET_ETHER_ADDR_LEN);
340
341 Ether->EtherType = HTONS (0x0800); // IPv4 protocol
342
343 Buf += sizeof (ETHER_HEAD);
344 BufLen -= sizeof (ETHER_HEAD);
345
346 //
347 // Fill in the IP header
348 //
349 Ip4 = (IP4_HEAD *) Buf;
350 Ip4->HeadLen = 5;
351 Ip4->Ver = 4;
352 Ip4->Tos = 0;
353 Ip4->TotalLen = 0;
354 Ip4->Id = (UINT16) mSyslogPacketSeq;
355 Ip4->Fragment = 0;
356 Ip4->Ttl = 16;
357 Ip4->Protocol = 0x11;
358 Ip4->Checksum = 0;
359 Ip4->Src = mSyslogSrcIp;
360 Ip4->Dst = mSyslogDstIp;
361
362 Buf += sizeof (IP4_HEAD);
363 BufLen -= sizeof (IP4_HEAD);
364
365 //
366 // Fill in the UDP header, Udp checksum is optional. Leave it zero.
367 //
368 Udp4 = (EFI_UDP_HEADER *) Buf;
369 Udp4->SrcPort = HTONS (514);
370 Udp4->DstPort = HTONS (514);
371 Udp4->Length = 0;
372 Udp4->Checksum = 0;
373
374 Buf += sizeof (EFI_UDP_HEADER);
375 BufLen -= sizeof (EFI_UDP_HEADER);
376
377 //
378 // Build the syslog message body with <PRI> Timestamp machine module Message
379 //
380 Pri = ((NET_SYSLOG_FACILITY & 31) << 3) | (Level & 7);
381 gRT->GetTime (&Time, NULL);
382 ASSERT ((Time.Month <= 12) && (Time.Month >= 1));
383
384 //
385 // Use %a to format the ASCII strings, %s to format UNICODE strings
386 //
387 Len = 0;
388 Len += (UINT32) AsciiSPrint (
389 Buf,
390 BufLen,
391 "<%d> %a %d %d:%d:%d ",
392 Pri,
393 mMonthName [Time.Month-1],
394 Time.Day,
395 Time.Hour,
396 Time.Minute,
397 Time.Second
398 );
399 Len--;
400
401 Len += (UINT32) AsciiSPrint (
402 Buf + Len,
403 BufLen - Len,
404 "Tiano %a: %a (Line: %d File: %a)",
405 Module,
406 Message,
407 Line,
408 File
409 );
410 Len--;
411
412 //
413 // OK, patch the IP length/checksum and UDP length fields.
414 //
415 Len += sizeof (EFI_UDP_HEADER);
416 Udp4->Length = HTONS ((UINT16) Len);
417
418 Len += sizeof (IP4_HEAD);
419 Ip4->TotalLen = HTONS ((UINT16) Len);
420 Ip4->Checksum = (UINT16) (~NetblockChecksum ((UINT8 *) Ip4, sizeof (IP4_HEAD)));
421
422 return Len + sizeof (ETHER_HEAD);
423 }
424
425 /**
426 Allocate a buffer, then format the message to it. This is a
427 help function for the NET_DEBUG_XXX macros. The PrintArg of
428 these macros treats the variable length print parameters as a
429 single parameter, and pass it to the NetDebugASPrint. For
430 example, NET_DEBUG_TRACE ("Tcp", ("State transit to %a\n", Name))
431 if extracted to:
432
433 NetDebugOutput (
434 NETDEBUG_LEVEL_TRACE,
435 "Tcp",
436 __FILE__,
437 __LINE__,
438 NetDebugASPrint ("State transit to %a\n", Name)
439 )
440
441 @param Format The ASCII format string.
442 @param ... The variable length parameter whose format is determined
443 by the Format string.
444
445 @return The buffer containing the formatted message,
446 or NULL if failed to allocate memory.
447
448 **/
449 CHAR8 *
450 EFIAPI
NetDebugASPrint(IN CHAR8 * Format,...)451 NetDebugASPrint (
452 IN CHAR8 *Format,
453 ...
454 )
455 {
456 VA_LIST Marker;
457 CHAR8 *Buf;
458
459 Buf = (CHAR8 *) AllocatePool (NET_DEBUG_MSG_LEN);
460
461 if (Buf == NULL) {
462 return NULL;
463 }
464
465 VA_START (Marker, Format);
466 AsciiVSPrint (Buf, NET_DEBUG_MSG_LEN, Format, Marker);
467 VA_END (Marker);
468
469 return Buf;
470 }
471
472 /**
473 Builds an UDP4 syslog packet and send it using SNP.
474
475 This function will locate a instance of SNP then send the message through it.
476 Because it isn't open the SNP BY_DRIVER, apply caution when using it.
477
478 @param Level The severity level of the message.
479 @param Module The Moudle that generates the log.
480 @param File The file that contains the log.
481 @param Line The exact line that contains the log.
482 @param Message The user message to log.
483
484 @retval EFI_INVALID_PARAMETER Any input parameter is invalid.
485 @retval EFI_OUT_OF_RESOURCES Failed to allocate memory for the packet
486 @retval EFI_SUCCESS The log is discard because that it is more verbose
487 than the mNetDebugLevelMax. Or, it has been sent out.
488 **/
489 EFI_STATUS
490 EFIAPI
NetDebugOutput(IN UINT32 Level,IN UINT8 * Module,IN UINT8 * File,IN UINT32 Line,IN UINT8 * Message)491 NetDebugOutput (
492 IN UINT32 Level,
493 IN UINT8 *Module,
494 IN UINT8 *File,
495 IN UINT32 Line,
496 IN UINT8 *Message
497 )
498 {
499 CHAR8 *Packet;
500 UINT32 Len;
501 EFI_STATUS Status;
502
503 //
504 // Check whether the message should be sent out
505 //
506 if (Message == NULL) {
507 return EFI_INVALID_PARAMETER;
508 }
509
510 if (Level > mNetDebugLevelMax) {
511 Status = EFI_SUCCESS;
512 goto ON_EXIT;
513 }
514
515 //
516 // Allocate a maxium of 1024 bytes, the caller should ensure
517 // that the message plus the ethernet/ip/udp header is shorter
518 // than this
519 //
520 Packet = (CHAR8 *) AllocatePool (NET_SYSLOG_PACKET_LEN);
521
522 if (Packet == NULL) {
523 Status = EFI_OUT_OF_RESOURCES;
524 goto ON_EXIT;
525 }
526
527 //
528 // Build the message: Ethernet header + IP header + Udp Header + user data
529 //
530 Len = SyslogBuildPacket (
531 Level,
532 Module,
533 File,
534 Line,
535 Message,
536 NET_SYSLOG_PACKET_LEN,
537 Packet
538 );
539
540 mSyslogPacketSeq++;
541 Status = SyslogSendPacket (Packet, Len);
542 FreePool (Packet);
543
544 ON_EXIT:
545 FreePool (Message);
546 return Status;
547 }
548 /**
549 Return the length of the mask.
550
551 Return the length of the mask, the correct value is from 0 to 32.
552 If the mask is invalid, return the invalid length 33, which is IP4_MASK_NUM.
553 NetMask is in the host byte order.
554
555 @param[in] NetMask The netmask to get the length from.
556
557 @return The length of the netmask, IP4_MASK_NUM if the mask is invalid.
558
559 **/
560 INTN
561 EFIAPI
NetGetMaskLength(IN IP4_ADDR NetMask)562 NetGetMaskLength (
563 IN IP4_ADDR NetMask
564 )
565 {
566 INTN Index;
567
568 for (Index = 0; Index <= IP4_MASK_MAX; Index++) {
569 if (NetMask == gIp4AllMasks[Index]) {
570 break;
571 }
572 }
573
574 return Index;
575 }
576
577
578
579 /**
580 Return the class of the IP address, such as class A, B, C.
581 Addr is in host byte order.
582
583 [ATTENTION]
584 Classful addressing (IP class A/B/C) has been deprecated according to RFC4632.
585 Caller of this function could only check the returned value against
586 IP4_ADDR_CLASSD (multicast) or IP4_ADDR_CLASSE (reserved) now.
587
588 The address of class A starts with 0.
589 If the address belong to class A, return IP4_ADDR_CLASSA.
590 The address of class B starts with 10.
591 If the address belong to class B, return IP4_ADDR_CLASSB.
592 The address of class C starts with 110.
593 If the address belong to class C, return IP4_ADDR_CLASSC.
594 The address of class D starts with 1110.
595 If the address belong to class D, return IP4_ADDR_CLASSD.
596 The address of class E starts with 1111.
597 If the address belong to class E, return IP4_ADDR_CLASSE.
598
599
600 @param[in] Addr The address to get the class from.
601
602 @return IP address class, such as IP4_ADDR_CLASSA.
603
604 **/
605 INTN
606 EFIAPI
NetGetIpClass(IN IP4_ADDR Addr)607 NetGetIpClass (
608 IN IP4_ADDR Addr
609 )
610 {
611 UINT8 ByteOne;
612
613 ByteOne = (UINT8) (Addr >> 24);
614
615 if ((ByteOne & 0x80) == 0) {
616 return IP4_ADDR_CLASSA;
617
618 } else if ((ByteOne & 0xC0) == 0x80) {
619 return IP4_ADDR_CLASSB;
620
621 } else if ((ByteOne & 0xE0) == 0xC0) {
622 return IP4_ADDR_CLASSC;
623
624 } else if ((ByteOne & 0xF0) == 0xE0) {
625 return IP4_ADDR_CLASSD;
626
627 } else {
628 return IP4_ADDR_CLASSE;
629
630 }
631 }
632
633
634 /**
635 Check whether the IP is a valid unicast address according to
636 the netmask.
637
638 ASSERT if NetMask is zero.
639
640 If all bits of the host address of IP are 0 or 1, IP is also not a valid unicast address.
641
642 @param[in] Ip The IP to check against.
643 @param[in] NetMask The mask of the IP.
644
645 @return TRUE if IP is a valid unicast address on the network, otherwise FALSE.
646
647 **/
648 BOOLEAN
649 EFIAPI
NetIp4IsUnicast(IN IP4_ADDR Ip,IN IP4_ADDR NetMask)650 NetIp4IsUnicast (
651 IN IP4_ADDR Ip,
652 IN IP4_ADDR NetMask
653 )
654 {
655 ASSERT (NetMask != 0);
656
657 if (Ip == 0 || IP4_IS_LOCAL_BROADCAST (Ip)) {
658 return FALSE;
659 }
660
661 if (((Ip &~NetMask) == ~NetMask) || ((Ip &~NetMask) == 0)) {
662 return FALSE;
663 }
664
665 return TRUE;
666 }
667
668 /**
669 Check whether the incoming IPv6 address is a valid unicast address.
670
671 If the address is a multicast address has binary 0xFF at the start, it is not
672 a valid unicast address. If the address is unspecified ::, it is not a valid
673 unicast address to be assigned to any node. If the address is loopback address
674 ::1, it is also not a valid unicast address to be assigned to any physical
675 interface.
676
677 @param[in] Ip6 The IPv6 address to check against.
678
679 @return TRUE if Ip6 is a valid unicast address on the network, otherwise FALSE.
680
681 **/
682 BOOLEAN
683 EFIAPI
NetIp6IsValidUnicast(IN EFI_IPv6_ADDRESS * Ip6)684 NetIp6IsValidUnicast (
685 IN EFI_IPv6_ADDRESS *Ip6
686 )
687 {
688 UINT8 Byte;
689 UINT8 Index;
690
691 if (Ip6->Addr[0] == 0xFF) {
692 return FALSE;
693 }
694
695 for (Index = 0; Index < 15; Index++) {
696 if (Ip6->Addr[Index] != 0) {
697 return TRUE;
698 }
699 }
700
701 Byte = Ip6->Addr[Index];
702
703 if (Byte == 0x0 || Byte == 0x1) {
704 return FALSE;
705 }
706
707 return TRUE;
708 }
709
710 /**
711 Check whether the incoming Ipv6 address is the unspecified address or not.
712
713 @param[in] Ip6 - Ip6 address, in network order.
714
715 @retval TRUE - Yes, unspecified
716 @retval FALSE - No
717
718 **/
719 BOOLEAN
720 EFIAPI
NetIp6IsUnspecifiedAddr(IN EFI_IPv6_ADDRESS * Ip6)721 NetIp6IsUnspecifiedAddr (
722 IN EFI_IPv6_ADDRESS *Ip6
723 )
724 {
725 UINT8 Index;
726
727 for (Index = 0; Index < 16; Index++) {
728 if (Ip6->Addr[Index] != 0) {
729 return FALSE;
730 }
731 }
732
733 return TRUE;
734 }
735
736 /**
737 Check whether the incoming Ipv6 address is a link-local address.
738
739 @param[in] Ip6 - Ip6 address, in network order.
740
741 @retval TRUE - Yes, link-local address
742 @retval FALSE - No
743
744 **/
745 BOOLEAN
746 EFIAPI
NetIp6IsLinkLocalAddr(IN EFI_IPv6_ADDRESS * Ip6)747 NetIp6IsLinkLocalAddr (
748 IN EFI_IPv6_ADDRESS *Ip6
749 )
750 {
751 UINT8 Index;
752
753 ASSERT (Ip6 != NULL);
754
755 if (Ip6->Addr[0] != 0xFE) {
756 return FALSE;
757 }
758
759 if (Ip6->Addr[1] != 0x80) {
760 return FALSE;
761 }
762
763 for (Index = 2; Index < 8; Index++) {
764 if (Ip6->Addr[Index] != 0) {
765 return FALSE;
766 }
767 }
768
769 return TRUE;
770 }
771
772 /**
773 Check whether the Ipv6 address1 and address2 are on the connected network.
774
775 @param[in] Ip1 - Ip6 address1, in network order.
776 @param[in] Ip2 - Ip6 address2, in network order.
777 @param[in] PrefixLength - The prefix length of the checking net.
778
779 @retval TRUE - Yes, connected.
780 @retval FALSE - No.
781
782 **/
783 BOOLEAN
784 EFIAPI
NetIp6IsNetEqual(EFI_IPv6_ADDRESS * Ip1,EFI_IPv6_ADDRESS * Ip2,UINT8 PrefixLength)785 NetIp6IsNetEqual (
786 EFI_IPv6_ADDRESS *Ip1,
787 EFI_IPv6_ADDRESS *Ip2,
788 UINT8 PrefixLength
789 )
790 {
791 UINT8 Byte;
792 UINT8 Bit;
793 UINT8 Mask;
794
795 ASSERT ((Ip1 != NULL) && (Ip2 != NULL) && (PrefixLength <= IP6_PREFIX_MAX));
796
797 if (PrefixLength == 0) {
798 return TRUE;
799 }
800
801 Byte = (UINT8) (PrefixLength / 8);
802 Bit = (UINT8) (PrefixLength % 8);
803
804 if (CompareMem (Ip1, Ip2, Byte) != 0) {
805 return FALSE;
806 }
807
808 if (Bit > 0) {
809 Mask = (UINT8) (0xFF << (8 - Bit));
810
811 ASSERT (Byte < 16);
812 if ((Ip1->Addr[Byte] & Mask) != (Ip2->Addr[Byte] & Mask)) {
813 return FALSE;
814 }
815 }
816
817 return TRUE;
818 }
819
820
821 /**
822 Switches the endianess of an IPv6 address
823
824 This function swaps the bytes in a 128-bit IPv6 address to switch the value
825 from little endian to big endian or vice versa. The byte swapped value is
826 returned.
827
828 @param Ip6 Points to an IPv6 address
829
830 @return The byte swapped IPv6 address.
831
832 **/
833 EFI_IPv6_ADDRESS *
834 EFIAPI
Ip6Swap128(EFI_IPv6_ADDRESS * Ip6)835 Ip6Swap128 (
836 EFI_IPv6_ADDRESS *Ip6
837 )
838 {
839 UINT64 High;
840 UINT64 Low;
841
842 CopyMem (&High, Ip6, sizeof (UINT64));
843 CopyMem (&Low, &Ip6->Addr[8], sizeof (UINT64));
844
845 High = SwapBytes64 (High);
846 Low = SwapBytes64 (Low);
847
848 CopyMem (Ip6, &Low, sizeof (UINT64));
849 CopyMem (&Ip6->Addr[8], &High, sizeof (UINT64));
850
851 return Ip6;
852 }
853
854 /**
855 Initialize a random seed using current time and monotonic count.
856
857 Get current time and monotonic count first. Then initialize a random seed
858 based on some basic mathematics operation on the hour, day, minute, second,
859 nanosecond and year of the current time and the monotonic count value.
860
861 @return The random seed initialized with current time.
862
863 **/
864 UINT32
865 EFIAPI
NetRandomInitSeed(VOID)866 NetRandomInitSeed (
867 VOID
868 )
869 {
870 EFI_TIME Time;
871 UINT32 Seed;
872 UINT64 MonotonicCount;
873
874 gRT->GetTime (&Time, NULL);
875 Seed = (~Time.Hour << 24 | Time.Day << 16 | Time.Minute << 8 | Time.Second);
876 Seed ^= Time.Nanosecond;
877 Seed ^= Time.Year << 7;
878
879 gBS->GetNextMonotonicCount (&MonotonicCount);
880 Seed += (UINT32) MonotonicCount;
881
882 return Seed;
883 }
884
885
886 /**
887 Extract a UINT32 from a byte stream.
888
889 Copy a UINT32 from a byte stream, then converts it from Network
890 byte order to host byte order. Use this function to avoid alignment error.
891
892 @param[in] Buf The buffer to extract the UINT32.
893
894 @return The UINT32 extracted.
895
896 **/
897 UINT32
898 EFIAPI
NetGetUint32(IN UINT8 * Buf)899 NetGetUint32 (
900 IN UINT8 *Buf
901 )
902 {
903 UINT32 Value;
904
905 CopyMem (&Value, Buf, sizeof (UINT32));
906 return NTOHL (Value);
907 }
908
909
910 /**
911 Put a UINT32 to the byte stream in network byte order.
912
913 Converts a UINT32 from host byte order to network byte order. Then copy it to the
914 byte stream.
915
916 @param[in, out] Buf The buffer to put the UINT32.
917 @param[in] Data The data to be converted and put into the byte stream.
918
919 **/
920 VOID
921 EFIAPI
NetPutUint32(IN OUT UINT8 * Buf,IN UINT32 Data)922 NetPutUint32 (
923 IN OUT UINT8 *Buf,
924 IN UINT32 Data
925 )
926 {
927 Data = HTONL (Data);
928 CopyMem (Buf, &Data, sizeof (UINT32));
929 }
930
931
932 /**
933 Remove the first node entry on the list, and return the removed node entry.
934
935 Removes the first node Entry from a doubly linked list. It is up to the caller of
936 this function to release the memory used by the first node if that is required. On
937 exit, the removed node is returned.
938
939 If Head is NULL, then ASSERT().
940 If Head was not initialized, then ASSERT().
941 If PcdMaximumLinkedListLength is not zero, and the number of nodes in the
942 linked list including the head node is greater than or equal to PcdMaximumLinkedListLength,
943 then ASSERT().
944
945 @param[in, out] Head The list header.
946
947 @return The first node entry that is removed from the list, NULL if the list is empty.
948
949 **/
950 LIST_ENTRY *
951 EFIAPI
NetListRemoveHead(IN OUT LIST_ENTRY * Head)952 NetListRemoveHead (
953 IN OUT LIST_ENTRY *Head
954 )
955 {
956 LIST_ENTRY *First;
957
958 ASSERT (Head != NULL);
959
960 if (IsListEmpty (Head)) {
961 return NULL;
962 }
963
964 First = Head->ForwardLink;
965 Head->ForwardLink = First->ForwardLink;
966 First->ForwardLink->BackLink = Head;
967
968 DEBUG_CODE (
969 First->ForwardLink = (LIST_ENTRY *) NULL;
970 First->BackLink = (LIST_ENTRY *) NULL;
971 );
972
973 return First;
974 }
975
976
977 /**
978 Remove the last node entry on the list and and return the removed node entry.
979
980 Removes the last node entry from a doubly linked list. It is up to the caller of
981 this function to release the memory used by the first node if that is required. On
982 exit, the removed node is returned.
983
984 If Head is NULL, then ASSERT().
985 If Head was not initialized, then ASSERT().
986 If PcdMaximumLinkedListLength is not zero, and the number of nodes in the
987 linked list including the head node is greater than or equal to PcdMaximumLinkedListLength,
988 then ASSERT().
989
990 @param[in, out] Head The list head.
991
992 @return The last node entry that is removed from the list, NULL if the list is empty.
993
994 **/
995 LIST_ENTRY *
996 EFIAPI
NetListRemoveTail(IN OUT LIST_ENTRY * Head)997 NetListRemoveTail (
998 IN OUT LIST_ENTRY *Head
999 )
1000 {
1001 LIST_ENTRY *Last;
1002
1003 ASSERT (Head != NULL);
1004
1005 if (IsListEmpty (Head)) {
1006 return NULL;
1007 }
1008
1009 Last = Head->BackLink;
1010 Head->BackLink = Last->BackLink;
1011 Last->BackLink->ForwardLink = Head;
1012
1013 DEBUG_CODE (
1014 Last->ForwardLink = (LIST_ENTRY *) NULL;
1015 Last->BackLink = (LIST_ENTRY *) NULL;
1016 );
1017
1018 return Last;
1019 }
1020
1021
1022 /**
1023 Insert a new node entry after a designated node entry of a doubly linked list.
1024
1025 Inserts a new node entry donated by NewEntry after the node entry donated by PrevEntry
1026 of the doubly linked list.
1027
1028 @param[in, out] PrevEntry The previous entry to insert after.
1029 @param[in, out] NewEntry The new entry to insert.
1030
1031 **/
1032 VOID
1033 EFIAPI
NetListInsertAfter(IN OUT LIST_ENTRY * PrevEntry,IN OUT LIST_ENTRY * NewEntry)1034 NetListInsertAfter (
1035 IN OUT LIST_ENTRY *PrevEntry,
1036 IN OUT LIST_ENTRY *NewEntry
1037 )
1038 {
1039 NewEntry->BackLink = PrevEntry;
1040 NewEntry->ForwardLink = PrevEntry->ForwardLink;
1041 PrevEntry->ForwardLink->BackLink = NewEntry;
1042 PrevEntry->ForwardLink = NewEntry;
1043 }
1044
1045
1046 /**
1047 Insert a new node entry before a designated node entry of a doubly linked list.
1048
1049 Inserts a new node entry donated by NewEntry after the node entry donated by PostEntry
1050 of the doubly linked list.
1051
1052 @param[in, out] PostEntry The entry to insert before.
1053 @param[in, out] NewEntry The new entry to insert.
1054
1055 **/
1056 VOID
1057 EFIAPI
NetListInsertBefore(IN OUT LIST_ENTRY * PostEntry,IN OUT LIST_ENTRY * NewEntry)1058 NetListInsertBefore (
1059 IN OUT LIST_ENTRY *PostEntry,
1060 IN OUT LIST_ENTRY *NewEntry
1061 )
1062 {
1063 NewEntry->ForwardLink = PostEntry;
1064 NewEntry->BackLink = PostEntry->BackLink;
1065 PostEntry->BackLink->ForwardLink = NewEntry;
1066 PostEntry->BackLink = NewEntry;
1067 }
1068
1069 /**
1070 Safe destroy nodes in a linked list, and return the length of the list after all possible operations finished.
1071
1072 Destroy network child instance list by list traversals is not safe due to graph dependencies between nodes.
1073 This function performs a safe traversal to destroy these nodes by checking to see if the node being destroyed
1074 has been removed from the list or not.
1075 If it has been removed, then restart the traversal from the head.
1076 If it hasn't been removed, then continue with the next node directly.
1077 This function will end the iterate and return the CallBack's last return value if error happens,
1078 or retrun EFI_SUCCESS if 2 complete passes are made with no changes in the number of children in the list.
1079
1080 @param[in] List The head of the list.
1081 @param[in] CallBack Pointer to the callback function to destroy one node in the list.
1082 @param[in] Context Pointer to the callback function's context: corresponds to the
1083 parameter Context in NET_DESTROY_LINK_LIST_CALLBACK.
1084 @param[out] ListLength The length of the link list if the function returns successfully.
1085
1086 @retval EFI_SUCCESS Two complete passes are made with no changes in the number of children.
1087 @retval EFI_INVALID_PARAMETER The input parameter is invalid.
1088 @retval Others Return the CallBack's last return value.
1089
1090 **/
1091 EFI_STATUS
1092 EFIAPI
NetDestroyLinkList(IN LIST_ENTRY * List,IN NET_DESTROY_LINK_LIST_CALLBACK CallBack,IN VOID * Context,OPTIONAL OUT UINTN * ListLength OPTIONAL)1093 NetDestroyLinkList (
1094 IN LIST_ENTRY *List,
1095 IN NET_DESTROY_LINK_LIST_CALLBACK CallBack,
1096 IN VOID *Context, OPTIONAL
1097 OUT UINTN *ListLength OPTIONAL
1098 )
1099 {
1100 UINTN PreviousLength;
1101 LIST_ENTRY *Entry;
1102 LIST_ENTRY *Ptr;
1103 UINTN Length;
1104 EFI_STATUS Status;
1105
1106 if (List == NULL || CallBack == NULL) {
1107 return EFI_INVALID_PARAMETER;
1108 }
1109
1110 Length = 0;
1111 do {
1112 PreviousLength = Length;
1113 Entry = GetFirstNode (List);
1114 while (!IsNull (List, Entry)) {
1115 Status = CallBack (Entry, Context);
1116 if (EFI_ERROR (Status)) {
1117 return Status;
1118 }
1119 //
1120 // Walk through the list to see whether the Entry has been removed or not.
1121 // If the Entry still exists, just try to destroy the next one.
1122 // If not, go back to the start point to iterate the list again.
1123 //
1124 for (Ptr = List->ForwardLink; Ptr != List; Ptr = Ptr->ForwardLink) {
1125 if (Ptr == Entry) {
1126 break;
1127 }
1128 }
1129 if (Ptr == Entry) {
1130 Entry = GetNextNode (List, Entry);
1131 } else {
1132 Entry = GetFirstNode (List);
1133 }
1134 }
1135 for (Length = 0, Ptr = List->ForwardLink; Ptr != List; Length++, Ptr = Ptr->ForwardLink);
1136 } while (Length != PreviousLength);
1137
1138 if (ListLength != NULL) {
1139 *ListLength = Length;
1140 }
1141 return EFI_SUCCESS;
1142 }
1143
1144 /**
1145 This function checks the input Handle to see if it's one of these handles in ChildHandleBuffer.
1146
1147 @param[in] Handle Handle to be checked.
1148 @param[in] NumberOfChildren Number of Handles in ChildHandleBuffer.
1149 @param[in] ChildHandleBuffer An array of child handles to be freed. May be NULL
1150 if NumberOfChildren is 0.
1151
1152 @retval TRUE Found the input Handle in ChildHandleBuffer.
1153 @retval FALSE Can't find the input Handle in ChildHandleBuffer.
1154
1155 **/
1156 BOOLEAN
1157 EFIAPI
NetIsInHandleBuffer(IN EFI_HANDLE Handle,IN UINTN NumberOfChildren,IN EFI_HANDLE * ChildHandleBuffer OPTIONAL)1158 NetIsInHandleBuffer (
1159 IN EFI_HANDLE Handle,
1160 IN UINTN NumberOfChildren,
1161 IN EFI_HANDLE *ChildHandleBuffer OPTIONAL
1162 )
1163 {
1164 UINTN Index;
1165
1166 if (NumberOfChildren == 0 || ChildHandleBuffer == NULL) {
1167 return FALSE;
1168 }
1169
1170 for (Index = 0; Index < NumberOfChildren; Index++) {
1171 if (Handle == ChildHandleBuffer[Index]) {
1172 return TRUE;
1173 }
1174 }
1175
1176 return FALSE;
1177 }
1178
1179
1180 /**
1181 Initialize the netmap. Netmap is a reposity to keep the <Key, Value> pairs.
1182
1183 Initialize the forward and backward links of two head nodes donated by Map->Used
1184 and Map->Recycled of two doubly linked lists.
1185 Initializes the count of the <Key, Value> pairs in the netmap to zero.
1186
1187 If Map is NULL, then ASSERT().
1188 If the address of Map->Used is NULL, then ASSERT().
1189 If the address of Map->Recycled is NULl, then ASSERT().
1190
1191 @param[in, out] Map The netmap to initialize.
1192
1193 **/
1194 VOID
1195 EFIAPI
NetMapInit(IN OUT NET_MAP * Map)1196 NetMapInit (
1197 IN OUT NET_MAP *Map
1198 )
1199 {
1200 ASSERT (Map != NULL);
1201
1202 InitializeListHead (&Map->Used);
1203 InitializeListHead (&Map->Recycled);
1204 Map->Count = 0;
1205 }
1206
1207
1208 /**
1209 To clean up the netmap, that is, release allocated memories.
1210
1211 Removes all nodes of the Used doubly linked list and free memory of all related netmap items.
1212 Removes all nodes of the Recycled doubly linked list and free memory of all related netmap items.
1213 The number of the <Key, Value> pairs in the netmap is set to be zero.
1214
1215 If Map is NULL, then ASSERT().
1216
1217 @param[in, out] Map The netmap to clean up.
1218
1219 **/
1220 VOID
1221 EFIAPI
NetMapClean(IN OUT NET_MAP * Map)1222 NetMapClean (
1223 IN OUT NET_MAP *Map
1224 )
1225 {
1226 NET_MAP_ITEM *Item;
1227 LIST_ENTRY *Entry;
1228 LIST_ENTRY *Next;
1229
1230 ASSERT (Map != NULL);
1231
1232 NET_LIST_FOR_EACH_SAFE (Entry, Next, &Map->Used) {
1233 Item = NET_LIST_USER_STRUCT (Entry, NET_MAP_ITEM, Link);
1234
1235 RemoveEntryList (&Item->Link);
1236 Map->Count--;
1237
1238 gBS->FreePool (Item);
1239 }
1240
1241 ASSERT ((Map->Count == 0) && IsListEmpty (&Map->Used));
1242
1243 NET_LIST_FOR_EACH_SAFE (Entry, Next, &Map->Recycled) {
1244 Item = NET_LIST_USER_STRUCT (Entry, NET_MAP_ITEM, Link);
1245
1246 RemoveEntryList (&Item->Link);
1247 gBS->FreePool (Item);
1248 }
1249
1250 ASSERT (IsListEmpty (&Map->Recycled));
1251 }
1252
1253
1254 /**
1255 Test whether the netmap is empty and return true if it is.
1256
1257 If the number of the <Key, Value> pairs in the netmap is zero, return TRUE.
1258
1259 If Map is NULL, then ASSERT().
1260
1261
1262 @param[in] Map The net map to test.
1263
1264 @return TRUE if the netmap is empty, otherwise FALSE.
1265
1266 **/
1267 BOOLEAN
1268 EFIAPI
NetMapIsEmpty(IN NET_MAP * Map)1269 NetMapIsEmpty (
1270 IN NET_MAP *Map
1271 )
1272 {
1273 ASSERT (Map != NULL);
1274 return (BOOLEAN) (Map->Count == 0);
1275 }
1276
1277
1278 /**
1279 Return the number of the <Key, Value> pairs in the netmap.
1280
1281 @param[in] Map The netmap to get the entry number.
1282
1283 @return The entry number in the netmap.
1284
1285 **/
1286 UINTN
1287 EFIAPI
NetMapGetCount(IN NET_MAP * Map)1288 NetMapGetCount (
1289 IN NET_MAP *Map
1290 )
1291 {
1292 return Map->Count;
1293 }
1294
1295
1296 /**
1297 Return one allocated item.
1298
1299 If the Recycled doubly linked list of the netmap is empty, it will try to allocate
1300 a batch of items if there are enough resources and add corresponding nodes to the begining
1301 of the Recycled doubly linked list of the netmap. Otherwise, it will directly remove
1302 the fist node entry of the Recycled doubly linked list and return the corresponding item.
1303
1304 If Map is NULL, then ASSERT().
1305
1306 @param[in, out] Map The netmap to allocate item for.
1307
1308 @return The allocated item. If NULL, the
1309 allocation failed due to resource limit.
1310
1311 **/
1312 NET_MAP_ITEM *
NetMapAllocItem(IN OUT NET_MAP * Map)1313 NetMapAllocItem (
1314 IN OUT NET_MAP *Map
1315 )
1316 {
1317 NET_MAP_ITEM *Item;
1318 LIST_ENTRY *Head;
1319 UINTN Index;
1320
1321 ASSERT (Map != NULL);
1322
1323 Head = &Map->Recycled;
1324
1325 if (IsListEmpty (Head)) {
1326 for (Index = 0; Index < NET_MAP_INCREAMENT; Index++) {
1327 Item = AllocatePool (sizeof (NET_MAP_ITEM));
1328
1329 if (Item == NULL) {
1330 if (Index == 0) {
1331 return NULL;
1332 }
1333
1334 break;
1335 }
1336
1337 InsertHeadList (Head, &Item->Link);
1338 }
1339 }
1340
1341 Item = NET_LIST_HEAD (Head, NET_MAP_ITEM, Link);
1342 NetListRemoveHead (Head);
1343
1344 return Item;
1345 }
1346
1347
1348 /**
1349 Allocate an item to save the <Key, Value> pair to the head of the netmap.
1350
1351 Allocate an item to save the <Key, Value> pair and add corresponding node entry
1352 to the beginning of the Used doubly linked list. The number of the <Key, Value>
1353 pairs in the netmap increase by 1.
1354
1355 If Map is NULL, then ASSERT().
1356
1357 @param[in, out] Map The netmap to insert into.
1358 @param[in] Key The user's key.
1359 @param[in] Value The user's value for the key.
1360
1361 @retval EFI_OUT_OF_RESOURCES Failed to allocate the memory for the item.
1362 @retval EFI_SUCCESS The item is inserted to the head.
1363
1364 **/
1365 EFI_STATUS
1366 EFIAPI
NetMapInsertHead(IN OUT NET_MAP * Map,IN VOID * Key,IN VOID * Value OPTIONAL)1367 NetMapInsertHead (
1368 IN OUT NET_MAP *Map,
1369 IN VOID *Key,
1370 IN VOID *Value OPTIONAL
1371 )
1372 {
1373 NET_MAP_ITEM *Item;
1374
1375 ASSERT (Map != NULL);
1376
1377 Item = NetMapAllocItem (Map);
1378
1379 if (Item == NULL) {
1380 return EFI_OUT_OF_RESOURCES;
1381 }
1382
1383 Item->Key = Key;
1384 Item->Value = Value;
1385 InsertHeadList (&Map->Used, &Item->Link);
1386
1387 Map->Count++;
1388 return EFI_SUCCESS;
1389 }
1390
1391
1392 /**
1393 Allocate an item to save the <Key, Value> pair to the tail of the netmap.
1394
1395 Allocate an item to save the <Key, Value> pair and add corresponding node entry
1396 to the tail of the Used doubly linked list. The number of the <Key, Value>
1397 pairs in the netmap increase by 1.
1398
1399 If Map is NULL, then ASSERT().
1400
1401 @param[in, out] Map The netmap to insert into.
1402 @param[in] Key The user's key.
1403 @param[in] Value The user's value for the key.
1404
1405 @retval EFI_OUT_OF_RESOURCES Failed to allocate the memory for the item.
1406 @retval EFI_SUCCESS The item is inserted to the tail.
1407
1408 **/
1409 EFI_STATUS
1410 EFIAPI
NetMapInsertTail(IN OUT NET_MAP * Map,IN VOID * Key,IN VOID * Value OPTIONAL)1411 NetMapInsertTail (
1412 IN OUT NET_MAP *Map,
1413 IN VOID *Key,
1414 IN VOID *Value OPTIONAL
1415 )
1416 {
1417 NET_MAP_ITEM *Item;
1418
1419 ASSERT (Map != NULL);
1420
1421 Item = NetMapAllocItem (Map);
1422
1423 if (Item == NULL) {
1424 return EFI_OUT_OF_RESOURCES;
1425 }
1426
1427 Item->Key = Key;
1428 Item->Value = Value;
1429 InsertTailList (&Map->Used, &Item->Link);
1430
1431 Map->Count++;
1432
1433 return EFI_SUCCESS;
1434 }
1435
1436
1437 /**
1438 Check whether the item is in the Map and return TRUE if it is.
1439
1440 @param[in] Map The netmap to search within.
1441 @param[in] Item The item to search.
1442
1443 @return TRUE if the item is in the netmap, otherwise FALSE.
1444
1445 **/
1446 BOOLEAN
NetItemInMap(IN NET_MAP * Map,IN NET_MAP_ITEM * Item)1447 NetItemInMap (
1448 IN NET_MAP *Map,
1449 IN NET_MAP_ITEM *Item
1450 )
1451 {
1452 LIST_ENTRY *ListEntry;
1453
1454 NET_LIST_FOR_EACH (ListEntry, &Map->Used) {
1455 if (ListEntry == &Item->Link) {
1456 return TRUE;
1457 }
1458 }
1459
1460 return FALSE;
1461 }
1462
1463
1464 /**
1465 Find the key in the netmap and returns the point to the item contains the Key.
1466
1467 Iterate the Used doubly linked list of the netmap to get every item. Compare the key of every
1468 item with the key to search. It returns the point to the item contains the Key if found.
1469
1470 If Map is NULL, then ASSERT().
1471
1472 @param[in] Map The netmap to search within.
1473 @param[in] Key The key to search.
1474
1475 @return The point to the item contains the Key, or NULL if Key isn't in the map.
1476
1477 **/
1478 NET_MAP_ITEM *
1479 EFIAPI
NetMapFindKey(IN NET_MAP * Map,IN VOID * Key)1480 NetMapFindKey (
1481 IN NET_MAP *Map,
1482 IN VOID *Key
1483 )
1484 {
1485 LIST_ENTRY *Entry;
1486 NET_MAP_ITEM *Item;
1487
1488 ASSERT (Map != NULL);
1489
1490 NET_LIST_FOR_EACH (Entry, &Map->Used) {
1491 Item = NET_LIST_USER_STRUCT (Entry, NET_MAP_ITEM, Link);
1492
1493 if (Item->Key == Key) {
1494 return Item;
1495 }
1496 }
1497
1498 return NULL;
1499 }
1500
1501
1502 /**
1503 Remove the node entry of the item from the netmap and return the key of the removed item.
1504
1505 Remove the node entry of the item from the Used doubly linked list of the netmap.
1506 The number of the <Key, Value> pairs in the netmap decrease by 1. Then add the node
1507 entry of the item to the Recycled doubly linked list of the netmap. If Value is not NULL,
1508 Value will point to the value of the item. It returns the key of the removed item.
1509
1510 If Map is NULL, then ASSERT().
1511 If Item is NULL, then ASSERT().
1512 if item in not in the netmap, then ASSERT().
1513
1514 @param[in, out] Map The netmap to remove the item from.
1515 @param[in, out] Item The item to remove.
1516 @param[out] Value The variable to receive the value if not NULL.
1517
1518 @return The key of the removed item.
1519
1520 **/
1521 VOID *
1522 EFIAPI
NetMapRemoveItem(IN OUT NET_MAP * Map,IN OUT NET_MAP_ITEM * Item,OUT VOID ** Value OPTIONAL)1523 NetMapRemoveItem (
1524 IN OUT NET_MAP *Map,
1525 IN OUT NET_MAP_ITEM *Item,
1526 OUT VOID **Value OPTIONAL
1527 )
1528 {
1529 ASSERT ((Map != NULL) && (Item != NULL));
1530 ASSERT (NetItemInMap (Map, Item));
1531
1532 RemoveEntryList (&Item->Link);
1533 Map->Count--;
1534 InsertHeadList (&Map->Recycled, &Item->Link);
1535
1536 if (Value != NULL) {
1537 *Value = Item->Value;
1538 }
1539
1540 return Item->Key;
1541 }
1542
1543
1544 /**
1545 Remove the first node entry on the netmap and return the key of the removed item.
1546
1547 Remove the first node entry from the Used doubly linked list of the netmap.
1548 The number of the <Key, Value> pairs in the netmap decrease by 1. Then add the node
1549 entry to the Recycled doubly linked list of the netmap. If parameter Value is not NULL,
1550 parameter Value will point to the value of the item. It returns the key of the removed item.
1551
1552 If Map is NULL, then ASSERT().
1553 If the Used doubly linked list is empty, then ASSERT().
1554
1555 @param[in, out] Map The netmap to remove the head from.
1556 @param[out] Value The variable to receive the value if not NULL.
1557
1558 @return The key of the item removed.
1559
1560 **/
1561 VOID *
1562 EFIAPI
NetMapRemoveHead(IN OUT NET_MAP * Map,OUT VOID ** Value OPTIONAL)1563 NetMapRemoveHead (
1564 IN OUT NET_MAP *Map,
1565 OUT VOID **Value OPTIONAL
1566 )
1567 {
1568 NET_MAP_ITEM *Item;
1569
1570 //
1571 // Often, it indicates a programming error to remove
1572 // the first entry in an empty list
1573 //
1574 ASSERT (Map && !IsListEmpty (&Map->Used));
1575
1576 Item = NET_LIST_HEAD (&Map->Used, NET_MAP_ITEM, Link);
1577 RemoveEntryList (&Item->Link);
1578 Map->Count--;
1579 InsertHeadList (&Map->Recycled, &Item->Link);
1580
1581 if (Value != NULL) {
1582 *Value = Item->Value;
1583 }
1584
1585 return Item->Key;
1586 }
1587
1588
1589 /**
1590 Remove the last node entry on the netmap and return the key of the removed item.
1591
1592 Remove the last node entry from the Used doubly linked list of the netmap.
1593 The number of the <Key, Value> pairs in the netmap decrease by 1. Then add the node
1594 entry to the Recycled doubly linked list of the netmap. If parameter Value is not NULL,
1595 parameter Value will point to the value of the item. It returns the key of the removed item.
1596
1597 If Map is NULL, then ASSERT().
1598 If the Used doubly linked list is empty, then ASSERT().
1599
1600 @param[in, out] Map The netmap to remove the tail from.
1601 @param[out] Value The variable to receive the value if not NULL.
1602
1603 @return The key of the item removed.
1604
1605 **/
1606 VOID *
1607 EFIAPI
NetMapRemoveTail(IN OUT NET_MAP * Map,OUT VOID ** Value OPTIONAL)1608 NetMapRemoveTail (
1609 IN OUT NET_MAP *Map,
1610 OUT VOID **Value OPTIONAL
1611 )
1612 {
1613 NET_MAP_ITEM *Item;
1614
1615 //
1616 // Often, it indicates a programming error to remove
1617 // the last entry in an empty list
1618 //
1619 ASSERT (Map && !IsListEmpty (&Map->Used));
1620
1621 Item = NET_LIST_TAIL (&Map->Used, NET_MAP_ITEM, Link);
1622 RemoveEntryList (&Item->Link);
1623 Map->Count--;
1624 InsertHeadList (&Map->Recycled, &Item->Link);
1625
1626 if (Value != NULL) {
1627 *Value = Item->Value;
1628 }
1629
1630 return Item->Key;
1631 }
1632
1633
1634 /**
1635 Iterate through the netmap and call CallBack for each item.
1636
1637 It will continue the traverse if CallBack returns EFI_SUCCESS, otherwise, break
1638 from the loop. It returns the CallBack's last return value. This function is
1639 delete safe for the current item.
1640
1641 If Map is NULL, then ASSERT().
1642 If CallBack is NULL, then ASSERT().
1643
1644 @param[in] Map The Map to iterate through.
1645 @param[in] CallBack The callback function to call for each item.
1646 @param[in] Arg The opaque parameter to the callback.
1647
1648 @retval EFI_SUCCESS There is no item in the netmap or CallBack for each item
1649 return EFI_SUCCESS.
1650 @retval Others It returns the CallBack's last return value.
1651
1652 **/
1653 EFI_STATUS
1654 EFIAPI
NetMapIterate(IN NET_MAP * Map,IN NET_MAP_CALLBACK CallBack,IN VOID * Arg OPTIONAL)1655 NetMapIterate (
1656 IN NET_MAP *Map,
1657 IN NET_MAP_CALLBACK CallBack,
1658 IN VOID *Arg OPTIONAL
1659 )
1660 {
1661
1662 LIST_ENTRY *Entry;
1663 LIST_ENTRY *Next;
1664 LIST_ENTRY *Head;
1665 NET_MAP_ITEM *Item;
1666 EFI_STATUS Result;
1667
1668 ASSERT ((Map != NULL) && (CallBack != NULL));
1669
1670 Head = &Map->Used;
1671
1672 if (IsListEmpty (Head)) {
1673 return EFI_SUCCESS;
1674 }
1675
1676 NET_LIST_FOR_EACH_SAFE (Entry, Next, Head) {
1677 Item = NET_LIST_USER_STRUCT (Entry, NET_MAP_ITEM, Link);
1678 Result = CallBack (Map, Item, Arg);
1679
1680 if (EFI_ERROR (Result)) {
1681 return Result;
1682 }
1683 }
1684
1685 return EFI_SUCCESS;
1686 }
1687
1688
1689 /**
1690 This is the default unload handle for all the network drivers.
1691
1692 Disconnect the driver specified by ImageHandle from all the devices in the handle database.
1693 Uninstall all the protocols installed in the driver entry point.
1694
1695 @param[in] ImageHandle The drivers' driver image.
1696
1697 @retval EFI_SUCCESS The image is unloaded.
1698 @retval Others Failed to unload the image.
1699
1700 **/
1701 EFI_STATUS
1702 EFIAPI
NetLibDefaultUnload(IN EFI_HANDLE ImageHandle)1703 NetLibDefaultUnload (
1704 IN EFI_HANDLE ImageHandle
1705 )
1706 {
1707 EFI_STATUS Status;
1708 EFI_HANDLE *DeviceHandleBuffer;
1709 UINTN DeviceHandleCount;
1710 UINTN Index;
1711 UINTN Index2;
1712 EFI_DRIVER_BINDING_PROTOCOL *DriverBinding;
1713 EFI_COMPONENT_NAME_PROTOCOL *ComponentName;
1714 EFI_COMPONENT_NAME2_PROTOCOL *ComponentName2;
1715
1716 //
1717 // Get the list of all the handles in the handle database.
1718 // If there is an error getting the list, then the unload
1719 // operation fails.
1720 //
1721 Status = gBS->LocateHandleBuffer (
1722 AllHandles,
1723 NULL,
1724 NULL,
1725 &DeviceHandleCount,
1726 &DeviceHandleBuffer
1727 );
1728
1729 if (EFI_ERROR (Status)) {
1730 return Status;
1731 }
1732
1733 for (Index = 0; Index < DeviceHandleCount; Index++) {
1734 Status = gBS->HandleProtocol (
1735 DeviceHandleBuffer[Index],
1736 &gEfiDriverBindingProtocolGuid,
1737 (VOID **) &DriverBinding
1738 );
1739 if (EFI_ERROR (Status)) {
1740 continue;
1741 }
1742
1743 if (DriverBinding->ImageHandle != ImageHandle) {
1744 continue;
1745 }
1746
1747 //
1748 // Disconnect the driver specified by ImageHandle from all
1749 // the devices in the handle database.
1750 //
1751 for (Index2 = 0; Index2 < DeviceHandleCount; Index2++) {
1752 Status = gBS->DisconnectController (
1753 DeviceHandleBuffer[Index2],
1754 DriverBinding->DriverBindingHandle,
1755 NULL
1756 );
1757 }
1758
1759 //
1760 // Uninstall all the protocols installed in the driver entry point
1761 //
1762 gBS->UninstallProtocolInterface (
1763 DriverBinding->DriverBindingHandle,
1764 &gEfiDriverBindingProtocolGuid,
1765 DriverBinding
1766 );
1767
1768 Status = gBS->HandleProtocol (
1769 DeviceHandleBuffer[Index],
1770 &gEfiComponentNameProtocolGuid,
1771 (VOID **) &ComponentName
1772 );
1773 if (!EFI_ERROR (Status)) {
1774 gBS->UninstallProtocolInterface (
1775 DriverBinding->DriverBindingHandle,
1776 &gEfiComponentNameProtocolGuid,
1777 ComponentName
1778 );
1779 }
1780
1781 Status = gBS->HandleProtocol (
1782 DeviceHandleBuffer[Index],
1783 &gEfiComponentName2ProtocolGuid,
1784 (VOID **) &ComponentName2
1785 );
1786 if (!EFI_ERROR (Status)) {
1787 gBS->UninstallProtocolInterface (
1788 DriverBinding->DriverBindingHandle,
1789 &gEfiComponentName2ProtocolGuid,
1790 ComponentName2
1791 );
1792 }
1793 }
1794
1795 //
1796 // Free the buffer containing the list of handles from the handle database
1797 //
1798 if (DeviceHandleBuffer != NULL) {
1799 gBS->FreePool (DeviceHandleBuffer);
1800 }
1801
1802 return EFI_SUCCESS;
1803 }
1804
1805
1806
1807 /**
1808 Create a child of the service that is identified by ServiceBindingGuid.
1809
1810 Get the ServiceBinding Protocol first, then use it to create a child.
1811
1812 If ServiceBindingGuid is NULL, then ASSERT().
1813 If ChildHandle is NULL, then ASSERT().
1814
1815 @param[in] Controller The controller which has the service installed.
1816 @param[in] Image The image handle used to open service.
1817 @param[in] ServiceBindingGuid The service's Guid.
1818 @param[in, out] ChildHandle The handle to receive the create child.
1819
1820 @retval EFI_SUCCESS The child is successfully created.
1821 @retval Others Failed to create the child.
1822
1823 **/
1824 EFI_STATUS
1825 EFIAPI
NetLibCreateServiceChild(IN EFI_HANDLE Controller,IN EFI_HANDLE Image,IN EFI_GUID * ServiceBindingGuid,IN OUT EFI_HANDLE * ChildHandle)1826 NetLibCreateServiceChild (
1827 IN EFI_HANDLE Controller,
1828 IN EFI_HANDLE Image,
1829 IN EFI_GUID *ServiceBindingGuid,
1830 IN OUT EFI_HANDLE *ChildHandle
1831 )
1832 {
1833 EFI_STATUS Status;
1834 EFI_SERVICE_BINDING_PROTOCOL *Service;
1835
1836
1837 ASSERT ((ServiceBindingGuid != NULL) && (ChildHandle != NULL));
1838
1839 //
1840 // Get the ServiceBinding Protocol
1841 //
1842 Status = gBS->OpenProtocol (
1843 Controller,
1844 ServiceBindingGuid,
1845 (VOID **) &Service,
1846 Image,
1847 Controller,
1848 EFI_OPEN_PROTOCOL_GET_PROTOCOL
1849 );
1850
1851 if (EFI_ERROR (Status)) {
1852 return Status;
1853 }
1854
1855 //
1856 // Create a child
1857 //
1858 Status = Service->CreateChild (Service, ChildHandle);
1859 return Status;
1860 }
1861
1862
1863 /**
1864 Destroy a child of the service that is identified by ServiceBindingGuid.
1865
1866 Get the ServiceBinding Protocol first, then use it to destroy a child.
1867
1868 If ServiceBindingGuid is NULL, then ASSERT().
1869
1870 @param[in] Controller The controller which has the service installed.
1871 @param[in] Image The image handle used to open service.
1872 @param[in] ServiceBindingGuid The service's Guid.
1873 @param[in] ChildHandle The child to destroy.
1874
1875 @retval EFI_SUCCESS The child is successfully destroyed.
1876 @retval Others Failed to destroy the child.
1877
1878 **/
1879 EFI_STATUS
1880 EFIAPI
NetLibDestroyServiceChild(IN EFI_HANDLE Controller,IN EFI_HANDLE Image,IN EFI_GUID * ServiceBindingGuid,IN EFI_HANDLE ChildHandle)1881 NetLibDestroyServiceChild (
1882 IN EFI_HANDLE Controller,
1883 IN EFI_HANDLE Image,
1884 IN EFI_GUID *ServiceBindingGuid,
1885 IN EFI_HANDLE ChildHandle
1886 )
1887 {
1888 EFI_STATUS Status;
1889 EFI_SERVICE_BINDING_PROTOCOL *Service;
1890
1891 ASSERT (ServiceBindingGuid != NULL);
1892
1893 //
1894 // Get the ServiceBinding Protocol
1895 //
1896 Status = gBS->OpenProtocol (
1897 Controller,
1898 ServiceBindingGuid,
1899 (VOID **) &Service,
1900 Image,
1901 Controller,
1902 EFI_OPEN_PROTOCOL_GET_PROTOCOL
1903 );
1904
1905 if (EFI_ERROR (Status)) {
1906 return Status;
1907 }
1908
1909 //
1910 // destroy the child
1911 //
1912 Status = Service->DestroyChild (Service, ChildHandle);
1913 return Status;
1914 }
1915
1916 /**
1917 Get handle with Simple Network Protocol installed on it.
1918
1919 There should be MNP Service Binding Protocol installed on the input ServiceHandle.
1920 If Simple Network Protocol is already installed on the ServiceHandle, the
1921 ServiceHandle will be returned. If SNP is not installed on the ServiceHandle,
1922 try to find its parent handle with SNP installed.
1923
1924 @param[in] ServiceHandle The handle where network service binding protocols are
1925 installed on.
1926 @param[out] Snp The pointer to store the address of the SNP instance.
1927 This is an optional parameter that may be NULL.
1928
1929 @return The SNP handle, or NULL if not found.
1930
1931 **/
1932 EFI_HANDLE
1933 EFIAPI
NetLibGetSnpHandle(IN EFI_HANDLE ServiceHandle,OUT EFI_SIMPLE_NETWORK_PROTOCOL ** Snp OPTIONAL)1934 NetLibGetSnpHandle (
1935 IN EFI_HANDLE ServiceHandle,
1936 OUT EFI_SIMPLE_NETWORK_PROTOCOL **Snp OPTIONAL
1937 )
1938 {
1939 EFI_STATUS Status;
1940 EFI_SIMPLE_NETWORK_PROTOCOL *SnpInstance;
1941 EFI_DEVICE_PATH_PROTOCOL *DevicePath;
1942 EFI_HANDLE SnpHandle;
1943
1944 //
1945 // Try to open SNP from ServiceHandle
1946 //
1947 SnpInstance = NULL;
1948 Status = gBS->HandleProtocol (ServiceHandle, &gEfiSimpleNetworkProtocolGuid, (VOID **) &SnpInstance);
1949 if (!EFI_ERROR (Status)) {
1950 if (Snp != NULL) {
1951 *Snp = SnpInstance;
1952 }
1953 return ServiceHandle;
1954 }
1955
1956 //
1957 // Failed to open SNP, try to get SNP handle by LocateDevicePath()
1958 //
1959 DevicePath = DevicePathFromHandle (ServiceHandle);
1960 if (DevicePath == NULL) {
1961 return NULL;
1962 }
1963
1964 SnpHandle = NULL;
1965 Status = gBS->LocateDevicePath (&gEfiSimpleNetworkProtocolGuid, &DevicePath, &SnpHandle);
1966 if (EFI_ERROR (Status)) {
1967 //
1968 // Failed to find SNP handle
1969 //
1970 return NULL;
1971 }
1972
1973 Status = gBS->HandleProtocol (SnpHandle, &gEfiSimpleNetworkProtocolGuid, (VOID **) &SnpInstance);
1974 if (!EFI_ERROR (Status)) {
1975 if (Snp != NULL) {
1976 *Snp = SnpInstance;
1977 }
1978 return SnpHandle;
1979 }
1980
1981 return NULL;
1982 }
1983
1984 /**
1985 Retrieve VLAN ID of a VLAN device handle.
1986
1987 Search VLAN device path node in Device Path of specified ServiceHandle and
1988 return its VLAN ID. If no VLAN device path node found, then this ServiceHandle
1989 is not a VLAN device handle, and 0 will be returned.
1990
1991 @param[in] ServiceHandle The handle where network service binding protocols are
1992 installed on.
1993
1994 @return VLAN ID of the device handle, or 0 if not a VLAN device.
1995
1996 **/
1997 UINT16
1998 EFIAPI
NetLibGetVlanId(IN EFI_HANDLE ServiceHandle)1999 NetLibGetVlanId (
2000 IN EFI_HANDLE ServiceHandle
2001 )
2002 {
2003 EFI_DEVICE_PATH_PROTOCOL *DevicePath;
2004 EFI_DEVICE_PATH_PROTOCOL *Node;
2005
2006 DevicePath = DevicePathFromHandle (ServiceHandle);
2007 if (DevicePath == NULL) {
2008 return 0;
2009 }
2010
2011 Node = DevicePath;
2012 while (!IsDevicePathEnd (Node)) {
2013 if (Node->Type == MESSAGING_DEVICE_PATH && Node->SubType == MSG_VLAN_DP) {
2014 return ((VLAN_DEVICE_PATH *) Node)->VlanId;
2015 }
2016 Node = NextDevicePathNode (Node);
2017 }
2018
2019 return 0;
2020 }
2021
2022 /**
2023 Find VLAN device handle with specified VLAN ID.
2024
2025 The VLAN child device handle is created by VLAN Config Protocol on ControllerHandle.
2026 This function will append VLAN device path node to the parent device path,
2027 and then use LocateDevicePath() to find the correct VLAN device handle.
2028
2029 @param[in] ControllerHandle The handle where network service binding protocols are
2030 installed on.
2031 @param[in] VlanId The configured VLAN ID for the VLAN device.
2032
2033 @return The VLAN device handle, or NULL if not found.
2034
2035 **/
2036 EFI_HANDLE
2037 EFIAPI
NetLibGetVlanHandle(IN EFI_HANDLE ControllerHandle,IN UINT16 VlanId)2038 NetLibGetVlanHandle (
2039 IN EFI_HANDLE ControllerHandle,
2040 IN UINT16 VlanId
2041 )
2042 {
2043 EFI_DEVICE_PATH_PROTOCOL *ParentDevicePath;
2044 EFI_DEVICE_PATH_PROTOCOL *VlanDevicePath;
2045 EFI_DEVICE_PATH_PROTOCOL *DevicePath;
2046 VLAN_DEVICE_PATH VlanNode;
2047 EFI_HANDLE Handle;
2048
2049 ParentDevicePath = DevicePathFromHandle (ControllerHandle);
2050 if (ParentDevicePath == NULL) {
2051 return NULL;
2052 }
2053
2054 //
2055 // Construct VLAN device path
2056 //
2057 CopyMem (&VlanNode, &mNetVlanDevicePathTemplate, sizeof (VLAN_DEVICE_PATH));
2058 VlanNode.VlanId = VlanId;
2059 VlanDevicePath = AppendDevicePathNode (
2060 ParentDevicePath,
2061 (EFI_DEVICE_PATH_PROTOCOL *) &VlanNode
2062 );
2063 if (VlanDevicePath == NULL) {
2064 return NULL;
2065 }
2066
2067 //
2068 // Find VLAN device handle
2069 //
2070 Handle = NULL;
2071 DevicePath = VlanDevicePath;
2072 gBS->LocateDevicePath (
2073 &gEfiDevicePathProtocolGuid,
2074 &DevicePath,
2075 &Handle
2076 );
2077 if (!IsDevicePathEnd (DevicePath)) {
2078 //
2079 // Device path is not exactly match
2080 //
2081 Handle = NULL;
2082 }
2083
2084 FreePool (VlanDevicePath);
2085 return Handle;
2086 }
2087
2088 /**
2089 Get MAC address associated with the network service handle.
2090
2091 There should be MNP Service Binding Protocol installed on the input ServiceHandle.
2092 If SNP is installed on the ServiceHandle or its parent handle, MAC address will
2093 be retrieved from SNP. If no SNP found, try to get SNP mode data use MNP.
2094
2095 @param[in] ServiceHandle The handle where network service binding protocols are
2096 installed on.
2097 @param[out] MacAddress The pointer to store the returned MAC address.
2098 @param[out] AddressSize The length of returned MAC address.
2099
2100 @retval EFI_SUCCESS MAC address is returned successfully.
2101 @retval Others Failed to get SNP mode data.
2102
2103 **/
2104 EFI_STATUS
2105 EFIAPI
NetLibGetMacAddress(IN EFI_HANDLE ServiceHandle,OUT EFI_MAC_ADDRESS * MacAddress,OUT UINTN * AddressSize)2106 NetLibGetMacAddress (
2107 IN EFI_HANDLE ServiceHandle,
2108 OUT EFI_MAC_ADDRESS *MacAddress,
2109 OUT UINTN *AddressSize
2110 )
2111 {
2112 EFI_STATUS Status;
2113 EFI_SIMPLE_NETWORK_PROTOCOL *Snp;
2114 EFI_SIMPLE_NETWORK_MODE *SnpMode;
2115 EFI_SIMPLE_NETWORK_MODE SnpModeData;
2116 EFI_MANAGED_NETWORK_PROTOCOL *Mnp;
2117 EFI_SERVICE_BINDING_PROTOCOL *MnpSb;
2118 EFI_HANDLE *SnpHandle;
2119 EFI_HANDLE MnpChildHandle;
2120
2121 ASSERT (MacAddress != NULL);
2122 ASSERT (AddressSize != NULL);
2123
2124 //
2125 // Try to get SNP handle
2126 //
2127 Snp = NULL;
2128 SnpHandle = NetLibGetSnpHandle (ServiceHandle, &Snp);
2129 if (SnpHandle != NULL) {
2130 //
2131 // SNP found, use it directly
2132 //
2133 SnpMode = Snp->Mode;
2134 } else {
2135 //
2136 // Failed to get SNP handle, try to get MAC address from MNP
2137 //
2138 MnpChildHandle = NULL;
2139 Status = gBS->HandleProtocol (
2140 ServiceHandle,
2141 &gEfiManagedNetworkServiceBindingProtocolGuid,
2142 (VOID **) &MnpSb
2143 );
2144 if (EFI_ERROR (Status)) {
2145 return Status;
2146 }
2147
2148 //
2149 // Create a MNP child
2150 //
2151 Status = MnpSb->CreateChild (MnpSb, &MnpChildHandle);
2152 if (EFI_ERROR (Status)) {
2153 return Status;
2154 }
2155
2156 //
2157 // Open MNP protocol
2158 //
2159 Status = gBS->HandleProtocol (
2160 MnpChildHandle,
2161 &gEfiManagedNetworkProtocolGuid,
2162 (VOID **) &Mnp
2163 );
2164 if (EFI_ERROR (Status)) {
2165 MnpSb->DestroyChild (MnpSb, MnpChildHandle);
2166 return Status;
2167 }
2168
2169 //
2170 // Try to get SNP mode from MNP
2171 //
2172 Status = Mnp->GetModeData (Mnp, NULL, &SnpModeData);
2173 if (EFI_ERROR (Status) && (Status != EFI_NOT_STARTED)) {
2174 MnpSb->DestroyChild (MnpSb, MnpChildHandle);
2175 return Status;
2176 }
2177 SnpMode = &SnpModeData;
2178
2179 //
2180 // Destroy the MNP child
2181 //
2182 MnpSb->DestroyChild (MnpSb, MnpChildHandle);
2183 }
2184
2185 *AddressSize = SnpMode->HwAddressSize;
2186 CopyMem (MacAddress->Addr, SnpMode->CurrentAddress.Addr, SnpMode->HwAddressSize);
2187
2188 return EFI_SUCCESS;
2189 }
2190
2191 /**
2192 Convert MAC address of the NIC associated with specified Service Binding Handle
2193 to a unicode string. Callers are responsible for freeing the string storage.
2194
2195 Locate simple network protocol associated with the Service Binding Handle and
2196 get the mac address from SNP. Then convert the mac address into a unicode
2197 string. It takes 2 unicode characters to represent a 1 byte binary buffer.
2198 Plus one unicode character for the null-terminator.
2199
2200 @param[in] ServiceHandle The handle where network service binding protocol is
2201 installed on.
2202 @param[in] ImageHandle The image handle used to act as the agent handle to
2203 get the simple network protocol. This parameter is
2204 optional and may be NULL.
2205 @param[out] MacString The pointer to store the address of the string
2206 representation of the mac address.
2207
2208 @retval EFI_SUCCESS Convert the mac address a unicode string successfully.
2209 @retval EFI_OUT_OF_RESOURCES There are not enough memory resource.
2210 @retval Others Failed to open the simple network protocol.
2211
2212 **/
2213 EFI_STATUS
2214 EFIAPI
NetLibGetMacString(IN EFI_HANDLE ServiceHandle,IN EFI_HANDLE ImageHandle,OPTIONAL OUT CHAR16 ** MacString)2215 NetLibGetMacString (
2216 IN EFI_HANDLE ServiceHandle,
2217 IN EFI_HANDLE ImageHandle, OPTIONAL
2218 OUT CHAR16 **MacString
2219 )
2220 {
2221 EFI_STATUS Status;
2222 EFI_MAC_ADDRESS MacAddress;
2223 UINT8 *HwAddress;
2224 UINTN HwAddressSize;
2225 UINT16 VlanId;
2226 CHAR16 *String;
2227 UINTN Index;
2228
2229 ASSERT (MacString != NULL);
2230
2231 //
2232 // Get MAC address of the network device
2233 //
2234 Status = NetLibGetMacAddress (ServiceHandle, &MacAddress, &HwAddressSize);
2235 if (EFI_ERROR (Status)) {
2236 return Status;
2237 }
2238
2239 //
2240 // It takes 2 unicode characters to represent a 1 byte binary buffer.
2241 // If VLAN is configured, it will need extra 5 characters like "\0005".
2242 // Plus one unicode character for the null-terminator.
2243 //
2244 String = AllocateZeroPool ((2 * HwAddressSize + 5 + 1) * sizeof (CHAR16));
2245 if (String == NULL) {
2246 return EFI_OUT_OF_RESOURCES;
2247 }
2248 *MacString = String;
2249
2250 //
2251 // Convert the MAC address into a unicode string.
2252 //
2253 HwAddress = &MacAddress.Addr[0];
2254 for (Index = 0; Index < HwAddressSize; Index++) {
2255 String += UnicodeValueToString (String, PREFIX_ZERO | RADIX_HEX, *(HwAddress++), 2);
2256 }
2257
2258 //
2259 // Append VLAN ID if any
2260 //
2261 VlanId = NetLibGetVlanId (ServiceHandle);
2262 if (VlanId != 0) {
2263 *String++ = L'\\';
2264 String += UnicodeValueToString (String, PREFIX_ZERO | RADIX_HEX, VlanId, 4);
2265 }
2266
2267 //
2268 // Null terminate the Unicode string
2269 //
2270 *String = L'\0';
2271
2272 return EFI_SUCCESS;
2273 }
2274
2275 /**
2276 Detect media status for specified network device.
2277
2278 The underlying UNDI driver may or may not support reporting media status from
2279 GET_STATUS command (PXE_STATFLAGS_GET_STATUS_NO_MEDIA_SUPPORTED). This routine
2280 will try to invoke Snp->GetStatus() to get the media status: if media already
2281 present, it return directly; if media not present, it will stop SNP and then
2282 restart SNP to get the latest media status, this give chance to get the correct
2283 media status for old UNDI driver which doesn't support reporting media status
2284 from GET_STATUS command.
2285 Note: there will be two limitations for current algorithm:
2286 1) for UNDI with this capability, in case of cable is not attached, there will
2287 be an redundant Stop/Start() process;
2288 2) for UNDI without this capability, in case that network cable is attached when
2289 Snp->Initialize() is invoked while network cable is unattached later,
2290 NetLibDetectMedia() will report MediaPresent as TRUE, causing upper layer
2291 apps to wait for timeout time.
2292
2293 @param[in] ServiceHandle The handle where network service binding protocols are
2294 installed on.
2295 @param[out] MediaPresent The pointer to store the media status.
2296
2297 @retval EFI_SUCCESS Media detection success.
2298 @retval EFI_INVALID_PARAMETER ServiceHandle is not valid network device handle.
2299 @retval EFI_UNSUPPORTED Network device does not support media detection.
2300 @retval EFI_DEVICE_ERROR SNP is in unknown state.
2301
2302 **/
2303 EFI_STATUS
2304 EFIAPI
NetLibDetectMedia(IN EFI_HANDLE ServiceHandle,OUT BOOLEAN * MediaPresent)2305 NetLibDetectMedia (
2306 IN EFI_HANDLE ServiceHandle,
2307 OUT BOOLEAN *MediaPresent
2308 )
2309 {
2310 EFI_STATUS Status;
2311 EFI_HANDLE SnpHandle;
2312 EFI_SIMPLE_NETWORK_PROTOCOL *Snp;
2313 UINT32 InterruptStatus;
2314 UINT32 OldState;
2315 EFI_MAC_ADDRESS *MCastFilter;
2316 UINT32 MCastFilterCount;
2317 UINT32 EnableFilterBits;
2318 UINT32 DisableFilterBits;
2319 BOOLEAN ResetMCastFilters;
2320
2321 ASSERT (MediaPresent != NULL);
2322
2323 //
2324 // Get SNP handle
2325 //
2326 Snp = NULL;
2327 SnpHandle = NetLibGetSnpHandle (ServiceHandle, &Snp);
2328 if (SnpHandle == NULL) {
2329 return EFI_INVALID_PARAMETER;
2330 }
2331
2332 //
2333 // Check whether SNP support media detection
2334 //
2335 if (!Snp->Mode->MediaPresentSupported) {
2336 return EFI_UNSUPPORTED;
2337 }
2338
2339 //
2340 // Invoke Snp->GetStatus() to refresh MediaPresent field in SNP mode data
2341 //
2342 Status = Snp->GetStatus (Snp, &InterruptStatus, NULL);
2343 if (EFI_ERROR (Status)) {
2344 return Status;
2345 }
2346
2347 if (Snp->Mode->MediaPresent) {
2348 //
2349 // Media is present, return directly
2350 //
2351 *MediaPresent = TRUE;
2352 return EFI_SUCCESS;
2353 }
2354
2355 //
2356 // Till now, GetStatus() report no media; while, in case UNDI not support
2357 // reporting media status from GetStatus(), this media status may be incorrect.
2358 // So, we will stop SNP and then restart it to get the correct media status.
2359 //
2360 OldState = Snp->Mode->State;
2361 if (OldState >= EfiSimpleNetworkMaxState) {
2362 return EFI_DEVICE_ERROR;
2363 }
2364
2365 MCastFilter = NULL;
2366
2367 if (OldState == EfiSimpleNetworkInitialized) {
2368 //
2369 // SNP is already in use, need Shutdown/Stop and then Start/Initialize
2370 //
2371
2372 //
2373 // Backup current SNP receive filter settings
2374 //
2375 EnableFilterBits = Snp->Mode->ReceiveFilterSetting;
2376 DisableFilterBits = Snp->Mode->ReceiveFilterMask ^ EnableFilterBits;
2377
2378 ResetMCastFilters = TRUE;
2379 MCastFilterCount = Snp->Mode->MCastFilterCount;
2380 if (MCastFilterCount != 0) {
2381 MCastFilter = AllocateCopyPool (
2382 MCastFilterCount * sizeof (EFI_MAC_ADDRESS),
2383 Snp->Mode->MCastFilter
2384 );
2385 ASSERT (MCastFilter != NULL);
2386
2387 ResetMCastFilters = FALSE;
2388 }
2389
2390 //
2391 // Shutdown/Stop the simple network
2392 //
2393 Status = Snp->Shutdown (Snp);
2394 if (!EFI_ERROR (Status)) {
2395 Status = Snp->Stop (Snp);
2396 }
2397 if (EFI_ERROR (Status)) {
2398 goto Exit;
2399 }
2400
2401 //
2402 // Start/Initialize the simple network
2403 //
2404 Status = Snp->Start (Snp);
2405 if (!EFI_ERROR (Status)) {
2406 Status = Snp->Initialize (Snp, 0, 0);
2407 }
2408 if (EFI_ERROR (Status)) {
2409 goto Exit;
2410 }
2411
2412 //
2413 // Here we get the correct media status
2414 //
2415 *MediaPresent = Snp->Mode->MediaPresent;
2416
2417 //
2418 // Restore SNP receive filter settings
2419 //
2420 Status = Snp->ReceiveFilters (
2421 Snp,
2422 EnableFilterBits,
2423 DisableFilterBits,
2424 ResetMCastFilters,
2425 MCastFilterCount,
2426 MCastFilter
2427 );
2428
2429 if (MCastFilter != NULL) {
2430 FreePool (MCastFilter);
2431 }
2432
2433 return Status;
2434 }
2435
2436 //
2437 // SNP is not in use, it's in state of EfiSimpleNetworkStopped or EfiSimpleNetworkStarted
2438 //
2439 if (OldState == EfiSimpleNetworkStopped) {
2440 //
2441 // SNP not start yet, start it
2442 //
2443 Status = Snp->Start (Snp);
2444 if (EFI_ERROR (Status)) {
2445 goto Exit;
2446 }
2447 }
2448
2449 //
2450 // Initialize the simple network
2451 //
2452 Status = Snp->Initialize (Snp, 0, 0);
2453 if (EFI_ERROR (Status)) {
2454 Status = EFI_DEVICE_ERROR;
2455 goto Exit;
2456 }
2457
2458 //
2459 // Here we get the correct media status
2460 //
2461 *MediaPresent = Snp->Mode->MediaPresent;
2462
2463 //
2464 // Shut down the simple network
2465 //
2466 Snp->Shutdown (Snp);
2467
2468 Exit:
2469 if (OldState == EfiSimpleNetworkStopped) {
2470 //
2471 // Original SNP sate is Stopped, restore to original state
2472 //
2473 Snp->Stop (Snp);
2474 }
2475
2476 if (MCastFilter != NULL) {
2477 FreePool (MCastFilter);
2478 }
2479
2480 return Status;
2481 }
2482
2483 /**
2484 Check the default address used by the IPv4 driver is static or dynamic (acquired
2485 from DHCP).
2486
2487 If the controller handle does not have the EFI_IP4_CONFIG2_PROTOCOL installed, the
2488 default address is static. If failed to get the policy from Ip4 Config2 Protocol,
2489 the default address is static. Otherwise, get the result from Ip4 Config2 Protocol.
2490
2491 @param[in] Controller The controller handle which has the EFI_IP4_CONFIG2_PROTOCOL
2492 relative with the default address to judge.
2493
2494 @retval TRUE If the default address is static.
2495 @retval FALSE If the default address is acquired from DHCP.
2496
2497 **/
2498 BOOLEAN
NetLibDefaultAddressIsStatic(IN EFI_HANDLE Controller)2499 NetLibDefaultAddressIsStatic (
2500 IN EFI_HANDLE Controller
2501 )
2502 {
2503 EFI_STATUS Status;
2504 EFI_IP4_CONFIG2_PROTOCOL *Ip4Config2;
2505 UINTN DataSize;
2506 EFI_IP4_CONFIG2_POLICY Policy;
2507 BOOLEAN IsStatic;
2508
2509 Ip4Config2 = NULL;
2510
2511 DataSize = sizeof (EFI_IP4_CONFIG2_POLICY);
2512
2513 IsStatic = TRUE;
2514
2515 //
2516 // Get Ip4Config2 policy.
2517 //
2518 Status = gBS->HandleProtocol (Controller, &gEfiIp4Config2ProtocolGuid, (VOID **) &Ip4Config2);
2519 if (EFI_ERROR (Status)) {
2520 goto ON_EXIT;
2521 }
2522
2523 Status = Ip4Config2->GetData (Ip4Config2, Ip4Config2DataTypePolicy, &DataSize, &Policy);
2524 if (EFI_ERROR (Status)) {
2525 goto ON_EXIT;
2526 }
2527
2528 IsStatic = (BOOLEAN) (Policy == Ip4Config2PolicyStatic);
2529
2530 ON_EXIT:
2531
2532 return IsStatic;
2533 }
2534
2535 /**
2536 Create an IPv4 device path node.
2537
2538 The header type of IPv4 device path node is MESSAGING_DEVICE_PATH.
2539 The header subtype of IPv4 device path node is MSG_IPv4_DP.
2540 Get other info from parameters to make up the whole IPv4 device path node.
2541
2542 @param[in, out] Node Pointer to the IPv4 device path node.
2543 @param[in] Controller The controller handle.
2544 @param[in] LocalIp The local IPv4 address.
2545 @param[in] LocalPort The local port.
2546 @param[in] RemoteIp The remote IPv4 address.
2547 @param[in] RemotePort The remote port.
2548 @param[in] Protocol The protocol type in the IP header.
2549 @param[in] UseDefaultAddress Whether this instance is using default address or not.
2550
2551 **/
2552 VOID
2553 EFIAPI
NetLibCreateIPv4DPathNode(IN OUT IPv4_DEVICE_PATH * Node,IN EFI_HANDLE Controller,IN IP4_ADDR LocalIp,IN UINT16 LocalPort,IN IP4_ADDR RemoteIp,IN UINT16 RemotePort,IN UINT16 Protocol,IN BOOLEAN UseDefaultAddress)2554 NetLibCreateIPv4DPathNode (
2555 IN OUT IPv4_DEVICE_PATH *Node,
2556 IN EFI_HANDLE Controller,
2557 IN IP4_ADDR LocalIp,
2558 IN UINT16 LocalPort,
2559 IN IP4_ADDR RemoteIp,
2560 IN UINT16 RemotePort,
2561 IN UINT16 Protocol,
2562 IN BOOLEAN UseDefaultAddress
2563 )
2564 {
2565 Node->Header.Type = MESSAGING_DEVICE_PATH;
2566 Node->Header.SubType = MSG_IPv4_DP;
2567 SetDevicePathNodeLength (&Node->Header, sizeof (IPv4_DEVICE_PATH));
2568
2569 CopyMem (&Node->LocalIpAddress, &LocalIp, sizeof (EFI_IPv4_ADDRESS));
2570 CopyMem (&Node->RemoteIpAddress, &RemoteIp, sizeof (EFI_IPv4_ADDRESS));
2571
2572 Node->LocalPort = LocalPort;
2573 Node->RemotePort = RemotePort;
2574
2575 Node->Protocol = Protocol;
2576
2577 if (!UseDefaultAddress) {
2578 Node->StaticIpAddress = TRUE;
2579 } else {
2580 Node->StaticIpAddress = NetLibDefaultAddressIsStatic (Controller);
2581 }
2582
2583 //
2584 // Set the Gateway IP address to default value 0:0:0:0.
2585 // Set the Subnet mask to default value 255:255:255:0.
2586 //
2587 ZeroMem (&Node->GatewayIpAddress, sizeof (EFI_IPv4_ADDRESS));
2588 SetMem (&Node->SubnetMask, sizeof (EFI_IPv4_ADDRESS), 0xff);
2589 Node->SubnetMask.Addr[3] = 0;
2590 }
2591
2592 /**
2593 Create an IPv6 device path node.
2594
2595 The header type of IPv6 device path node is MESSAGING_DEVICE_PATH.
2596 The header subtype of IPv6 device path node is MSG_IPv6_DP.
2597 Get other info from parameters to make up the whole IPv6 device path node.
2598
2599 @param[in, out] Node Pointer to the IPv6 device path node.
2600 @param[in] Controller The controller handle.
2601 @param[in] LocalIp The local IPv6 address.
2602 @param[in] LocalPort The local port.
2603 @param[in] RemoteIp The remote IPv6 address.
2604 @param[in] RemotePort The remote port.
2605 @param[in] Protocol The protocol type in the IP header.
2606
2607 **/
2608 VOID
2609 EFIAPI
NetLibCreateIPv6DPathNode(IN OUT IPv6_DEVICE_PATH * Node,IN EFI_HANDLE Controller,IN EFI_IPv6_ADDRESS * LocalIp,IN UINT16 LocalPort,IN EFI_IPv6_ADDRESS * RemoteIp,IN UINT16 RemotePort,IN UINT16 Protocol)2610 NetLibCreateIPv6DPathNode (
2611 IN OUT IPv6_DEVICE_PATH *Node,
2612 IN EFI_HANDLE Controller,
2613 IN EFI_IPv6_ADDRESS *LocalIp,
2614 IN UINT16 LocalPort,
2615 IN EFI_IPv6_ADDRESS *RemoteIp,
2616 IN UINT16 RemotePort,
2617 IN UINT16 Protocol
2618 )
2619 {
2620 Node->Header.Type = MESSAGING_DEVICE_PATH;
2621 Node->Header.SubType = MSG_IPv6_DP;
2622 SetDevicePathNodeLength (&Node->Header, sizeof (IPv6_DEVICE_PATH));
2623
2624 CopyMem (&Node->LocalIpAddress, LocalIp, sizeof (EFI_IPv6_ADDRESS));
2625 CopyMem (&Node->RemoteIpAddress, RemoteIp, sizeof (EFI_IPv6_ADDRESS));
2626
2627 Node->LocalPort = LocalPort;
2628 Node->RemotePort = RemotePort;
2629
2630 Node->Protocol = Protocol;
2631
2632 //
2633 // Set default value to IPAddressOrigin, PrefixLength.
2634 // Set the Gateway IP address to unspecified address.
2635 //
2636 Node->IpAddressOrigin = 0;
2637 Node->PrefixLength = IP6_PREFIX_LENGTH;
2638 ZeroMem (&Node->GatewayIpAddress, sizeof (EFI_IPv6_ADDRESS));
2639 }
2640
2641 /**
2642 Find the UNDI/SNP handle from controller and protocol GUID.
2643
2644 For example, IP will open a MNP child to transmit/receive
2645 packets, when MNP is stopped, IP should also be stopped. IP
2646 needs to find its own private data which is related the IP's
2647 service binding instance that is install on UNDI/SNP handle.
2648 Now, the controller is either a MNP or ARP child handle. But
2649 IP opens these handle BY_DRIVER, use that info, we can get the
2650 UNDI/SNP handle.
2651
2652 @param[in] Controller Then protocol handle to check.
2653 @param[in] ProtocolGuid The protocol that is related with the handle.
2654
2655 @return The UNDI/SNP handle or NULL for errors.
2656
2657 **/
2658 EFI_HANDLE
2659 EFIAPI
NetLibGetNicHandle(IN EFI_HANDLE Controller,IN EFI_GUID * ProtocolGuid)2660 NetLibGetNicHandle (
2661 IN EFI_HANDLE Controller,
2662 IN EFI_GUID *ProtocolGuid
2663 )
2664 {
2665 EFI_OPEN_PROTOCOL_INFORMATION_ENTRY *OpenBuffer;
2666 EFI_HANDLE Handle;
2667 EFI_STATUS Status;
2668 UINTN OpenCount;
2669 UINTN Index;
2670
2671 Status = gBS->OpenProtocolInformation (
2672 Controller,
2673 ProtocolGuid,
2674 &OpenBuffer,
2675 &OpenCount
2676 );
2677
2678 if (EFI_ERROR (Status)) {
2679 return NULL;
2680 }
2681
2682 Handle = NULL;
2683
2684 for (Index = 0; Index < OpenCount; Index++) {
2685 if ((OpenBuffer[Index].Attributes & EFI_OPEN_PROTOCOL_BY_DRIVER) != 0) {
2686 Handle = OpenBuffer[Index].ControllerHandle;
2687 break;
2688 }
2689 }
2690
2691 gBS->FreePool (OpenBuffer);
2692 return Handle;
2693 }
2694
2695 /**
2696 Convert one Null-terminated ASCII string (decimal dotted) to EFI_IPv4_ADDRESS.
2697
2698 @param[in] String The pointer to the Ascii string.
2699 @param[out] Ip4Address The pointer to the converted IPv4 address.
2700
2701 @retval EFI_SUCCESS Convert to IPv4 address successfully.
2702 @retval EFI_INVALID_PARAMETER The string is mal-formated or Ip4Address is NULL.
2703
2704 **/
2705 EFI_STATUS
2706 EFIAPI
NetLibAsciiStrToIp4(IN CONST CHAR8 * String,OUT EFI_IPv4_ADDRESS * Ip4Address)2707 NetLibAsciiStrToIp4 (
2708 IN CONST CHAR8 *String,
2709 OUT EFI_IPv4_ADDRESS *Ip4Address
2710 )
2711 {
2712 UINT8 Index;
2713 CHAR8 *Ip4Str;
2714 CHAR8 *TempStr;
2715 UINTN NodeVal;
2716
2717 if ((String == NULL) || (Ip4Address == NULL)) {
2718 return EFI_INVALID_PARAMETER;
2719 }
2720
2721 Ip4Str = (CHAR8 *) String;
2722
2723 for (Index = 0; Index < 4; Index++) {
2724 TempStr = Ip4Str;
2725
2726 while ((*Ip4Str != '\0') && (*Ip4Str != '.')) {
2727 if (Index != 3 && !NET_IS_DIGIT (*Ip4Str)) {
2728 return EFI_INVALID_PARAMETER;
2729 }
2730
2731 //
2732 // Allow the IPv4 with prefix case, e.g. 192.168.10.10/24
2733 //
2734 if (Index == 3 && !NET_IS_DIGIT (*Ip4Str) && *Ip4Str != '/') {
2735 return EFI_INVALID_PARAMETER;
2736 }
2737
2738 Ip4Str++;
2739 }
2740
2741 //
2742 // The IPv4 address is X.X.X.X
2743 //
2744 if (*Ip4Str == '.') {
2745 if (Index == 3) {
2746 return EFI_INVALID_PARAMETER;
2747 }
2748 } else {
2749 if (Index != 3) {
2750 return EFI_INVALID_PARAMETER;
2751 }
2752 }
2753
2754 //
2755 // Convert the string to IPv4 address. AsciiStrDecimalToUintn stops at the
2756 // first character that is not a valid decimal character, '.' or '\0' here.
2757 //
2758 NodeVal = AsciiStrDecimalToUintn (TempStr);
2759 if (NodeVal > 0xFF) {
2760 return EFI_INVALID_PARAMETER;
2761 }
2762
2763 Ip4Address->Addr[Index] = (UINT8) NodeVal;
2764
2765 Ip4Str++;
2766 }
2767
2768 return EFI_SUCCESS;
2769 }
2770
2771
2772 /**
2773 Convert one Null-terminated ASCII string to EFI_IPv6_ADDRESS. The format of the
2774 string is defined in RFC 4291 - Text Representation of Addresses.
2775
2776 @param[in] String The pointer to the Ascii string.
2777 @param[out] Ip6Address The pointer to the converted IPv6 address.
2778
2779 @retval EFI_SUCCESS Convert to IPv6 address successfully.
2780 @retval EFI_INVALID_PARAMETER The string is mal-formated or Ip6Address is NULL.
2781
2782 **/
2783 EFI_STATUS
2784 EFIAPI
NetLibAsciiStrToIp6(IN CONST CHAR8 * String,OUT EFI_IPv6_ADDRESS * Ip6Address)2785 NetLibAsciiStrToIp6 (
2786 IN CONST CHAR8 *String,
2787 OUT EFI_IPv6_ADDRESS *Ip6Address
2788 )
2789 {
2790 UINT8 Index;
2791 CHAR8 *Ip6Str;
2792 CHAR8 *TempStr;
2793 CHAR8 *TempStr2;
2794 UINT8 NodeCnt;
2795 UINT8 TailNodeCnt;
2796 UINT8 AllowedCnt;
2797 UINTN NodeVal;
2798 BOOLEAN Short;
2799 BOOLEAN Update;
2800 BOOLEAN LeadZero;
2801 UINT8 LeadZeroCnt;
2802 UINT8 Cnt;
2803
2804 if ((String == NULL) || (Ip6Address == NULL)) {
2805 return EFI_INVALID_PARAMETER;
2806 }
2807
2808 Ip6Str = (CHAR8 *) String;
2809 AllowedCnt = 6;
2810 LeadZeroCnt = 0;
2811
2812 //
2813 // An IPv6 address leading with : looks strange.
2814 //
2815 if (*Ip6Str == ':') {
2816 if (*(Ip6Str + 1) != ':') {
2817 return EFI_INVALID_PARAMETER;
2818 } else {
2819 AllowedCnt = 7;
2820 }
2821 }
2822
2823 ZeroMem (Ip6Address, sizeof (EFI_IPv6_ADDRESS));
2824
2825 NodeCnt = 0;
2826 TailNodeCnt = 0;
2827 Short = FALSE;
2828 Update = FALSE;
2829 LeadZero = FALSE;
2830
2831 for (Index = 0; Index < 15; Index = (UINT8) (Index + 2)) {
2832 TempStr = Ip6Str;
2833
2834 while ((*Ip6Str != '\0') && (*Ip6Str != ':')) {
2835 if (Index != 14 && !NET_IS_HEX (*Ip6Str)) {
2836 return EFI_INVALID_PARAMETER;
2837 }
2838
2839 //
2840 // Allow the IPv6 with prefix case, e.g. 2000:aaaa::10/24
2841 //
2842 if (Index == 14 && !NET_IS_HEX (*Ip6Str) && *Ip6Str != '/') {
2843 return EFI_INVALID_PARAMETER;
2844 }
2845
2846 Ip6Str++;
2847 }
2848
2849 if ((*Ip6Str == '\0') && (Index != 14)) {
2850 return EFI_INVALID_PARAMETER;
2851 }
2852
2853 if (*Ip6Str == ':') {
2854 if (*(Ip6Str + 1) == ':') {
2855 if ((NodeCnt > 6) ||
2856 ((*(Ip6Str + 2) != '\0') && (AsciiStrHexToUintn (Ip6Str + 2) == 0))) {
2857 //
2858 // ::0 looks strange. report error to user.
2859 //
2860 return EFI_INVALID_PARAMETER;
2861 }
2862 if ((NodeCnt == 6) && (*(Ip6Str + 2) != '\0') &&
2863 (AsciiStrHexToUintn (Ip6Str + 2) != 0)) {
2864 return EFI_INVALID_PARAMETER;
2865 }
2866
2867 //
2868 // Skip the abbreviation part of IPv6 address.
2869 //
2870 TempStr2 = Ip6Str + 2;
2871 while ((*TempStr2 != '\0')) {
2872 if (*TempStr2 == ':') {
2873 if (*(TempStr2 + 1) == ':') {
2874 //
2875 // :: can only appear once in IPv6 address.
2876 //
2877 return EFI_INVALID_PARAMETER;
2878 }
2879
2880 TailNodeCnt++;
2881 if (TailNodeCnt >= (AllowedCnt - NodeCnt)) {
2882 //
2883 // :: indicates one or more groups of 16 bits of zeros.
2884 //
2885 return EFI_INVALID_PARAMETER;
2886 }
2887 }
2888
2889 TempStr2++;
2890 }
2891
2892 Short = TRUE;
2893 Update = TRUE;
2894
2895 Ip6Str = Ip6Str + 2;
2896 } else {
2897 if (*(Ip6Str + 1) == '\0') {
2898 return EFI_INVALID_PARAMETER;
2899 }
2900 Ip6Str++;
2901 NodeCnt++;
2902 if ((Short && (NodeCnt > 6)) || (!Short && (NodeCnt > 7))) {
2903 //
2904 // There are more than 8 groups of 16 bits of zeros.
2905 //
2906 return EFI_INVALID_PARAMETER;
2907 }
2908 }
2909 }
2910
2911 //
2912 // Convert the string to IPv6 address. AsciiStrHexToUintn stops at the first
2913 // character that is not a valid hexadecimal character, ':' or '\0' here.
2914 //
2915 NodeVal = AsciiStrHexToUintn (TempStr);
2916 if ((NodeVal > 0xFFFF) || (Index > 14)) {
2917 return EFI_INVALID_PARAMETER;
2918 }
2919 if (NodeVal != 0) {
2920 if ((*TempStr == '0') &&
2921 ((*(TempStr + 2) == ':') || (*(TempStr + 3) == ':') ||
2922 (*(TempStr + 2) == '\0') || (*(TempStr + 3) == '\0'))) {
2923 return EFI_INVALID_PARAMETER;
2924 }
2925 if ((*TempStr == '0') && (*(TempStr + 4) != '\0') &&
2926 (*(TempStr + 4) != ':')) {
2927 return EFI_INVALID_PARAMETER;
2928 }
2929 } else {
2930 if (((*TempStr == '0') && (*(TempStr + 1) == '0') &&
2931 ((*(TempStr + 2) == ':') || (*(TempStr + 2) == '\0'))) ||
2932 ((*TempStr == '0') && (*(TempStr + 1) == '0') && (*(TempStr + 2) == '0') &&
2933 ((*(TempStr + 3) == ':') || (*(TempStr + 3) == '\0')))) {
2934 return EFI_INVALID_PARAMETER;
2935 }
2936 }
2937
2938 Cnt = 0;
2939 while ((TempStr[Cnt] != ':') && (TempStr[Cnt] != '\0')) {
2940 Cnt++;
2941 }
2942 if (LeadZeroCnt == 0) {
2943 if ((Cnt == 4) && (*TempStr == '0')) {
2944 LeadZero = TRUE;
2945 LeadZeroCnt++;
2946 }
2947 if ((Cnt != 0) && (Cnt < 4)) {
2948 LeadZero = FALSE;
2949 LeadZeroCnt++;
2950 }
2951 } else {
2952 if ((Cnt == 4) && (*TempStr == '0') && !LeadZero) {
2953 return EFI_INVALID_PARAMETER;
2954 }
2955 if ((Cnt != 0) && (Cnt < 4) && LeadZero) {
2956 return EFI_INVALID_PARAMETER;
2957 }
2958 }
2959
2960 Ip6Address->Addr[Index] = (UINT8) (NodeVal >> 8);
2961 Ip6Address->Addr[Index + 1] = (UINT8) (NodeVal & 0xFF);
2962
2963 //
2964 // Skip the groups of zeros by ::
2965 //
2966 if (Short && Update) {
2967 Index = (UINT8) (16 - (TailNodeCnt + 2) * 2);
2968 Update = FALSE;
2969 }
2970 }
2971
2972 if ((!Short && Index != 16) || (*Ip6Str != '\0')) {
2973 return EFI_INVALID_PARAMETER;
2974 }
2975
2976 return EFI_SUCCESS;
2977 }
2978
2979
2980 /**
2981 Convert one Null-terminated Unicode string (decimal dotted) to EFI_IPv4_ADDRESS.
2982
2983 @param[in] String The pointer to the Ascii string.
2984 @param[out] Ip4Address The pointer to the converted IPv4 address.
2985
2986 @retval EFI_SUCCESS Convert to IPv4 address successfully.
2987 @retval EFI_INVALID_PARAMETER The string is mal-formated or Ip4Address is NULL.
2988 @retval EFI_OUT_OF_RESOURCES Fail to perform the operation due to lack of resource.
2989
2990 **/
2991 EFI_STATUS
2992 EFIAPI
NetLibStrToIp4(IN CONST CHAR16 * String,OUT EFI_IPv4_ADDRESS * Ip4Address)2993 NetLibStrToIp4 (
2994 IN CONST CHAR16 *String,
2995 OUT EFI_IPv4_ADDRESS *Ip4Address
2996 )
2997 {
2998 CHAR8 *Ip4Str;
2999 UINTN StringSize;
3000 EFI_STATUS Status;
3001
3002 if ((String == NULL) || (Ip4Address == NULL)) {
3003 return EFI_INVALID_PARAMETER;
3004 }
3005
3006 StringSize = StrLen (String) + 1;
3007 Ip4Str = (CHAR8 *) AllocatePool (StringSize * sizeof (CHAR8));
3008 if (Ip4Str == NULL) {
3009 return EFI_OUT_OF_RESOURCES;
3010 }
3011
3012 UnicodeStrToAsciiStrS (String, Ip4Str, StringSize);
3013
3014 Status = NetLibAsciiStrToIp4 (Ip4Str, Ip4Address);
3015
3016 FreePool (Ip4Str);
3017
3018 return Status;
3019 }
3020
3021
3022 /**
3023 Convert one Null-terminated Unicode string to EFI_IPv6_ADDRESS. The format of
3024 the string is defined in RFC 4291 - Text Representation of Addresses.
3025
3026 @param[in] String The pointer to the Ascii string.
3027 @param[out] Ip6Address The pointer to the converted IPv6 address.
3028
3029 @retval EFI_SUCCESS Convert to IPv6 address successfully.
3030 @retval EFI_INVALID_PARAMETER The string is mal-formated or Ip6Address is NULL.
3031 @retval EFI_OUT_OF_RESOURCES Fail to perform the operation due to lack of resource.
3032
3033 **/
3034 EFI_STATUS
3035 EFIAPI
NetLibStrToIp6(IN CONST CHAR16 * String,OUT EFI_IPv6_ADDRESS * Ip6Address)3036 NetLibStrToIp6 (
3037 IN CONST CHAR16 *String,
3038 OUT EFI_IPv6_ADDRESS *Ip6Address
3039 )
3040 {
3041 CHAR8 *Ip6Str;
3042 UINTN StringSize;
3043 EFI_STATUS Status;
3044
3045 if ((String == NULL) || (Ip6Address == NULL)) {
3046 return EFI_INVALID_PARAMETER;
3047 }
3048
3049 StringSize = StrLen (String) + 1;
3050 Ip6Str = (CHAR8 *) AllocatePool (StringSize * sizeof (CHAR8));
3051 if (Ip6Str == NULL) {
3052 return EFI_OUT_OF_RESOURCES;
3053 }
3054
3055 UnicodeStrToAsciiStrS (String, Ip6Str, StringSize);
3056
3057 Status = NetLibAsciiStrToIp6 (Ip6Str, Ip6Address);
3058
3059 FreePool (Ip6Str);
3060
3061 return Status;
3062 }
3063
3064 /**
3065 Convert one Null-terminated Unicode string to EFI_IPv6_ADDRESS and prefix length.
3066 The format of the string is defined in RFC 4291 - Text Representation of Addresses
3067 Prefixes: ipv6-address/prefix-length.
3068
3069 @param[in] String The pointer to the Ascii string.
3070 @param[out] Ip6Address The pointer to the converted IPv6 address.
3071 @param[out] PrefixLength The pointer to the converted prefix length.
3072
3073 @retval EFI_SUCCESS Convert to IPv6 address successfully.
3074 @retval EFI_INVALID_PARAMETER The string is mal-formated or Ip6Address is NULL.
3075 @retval EFI_OUT_OF_RESOURCES Fail to perform the operation due to lack of resource.
3076
3077 **/
3078 EFI_STATUS
3079 EFIAPI
NetLibStrToIp6andPrefix(IN CONST CHAR16 * String,OUT EFI_IPv6_ADDRESS * Ip6Address,OUT UINT8 * PrefixLength)3080 NetLibStrToIp6andPrefix (
3081 IN CONST CHAR16 *String,
3082 OUT EFI_IPv6_ADDRESS *Ip6Address,
3083 OUT UINT8 *PrefixLength
3084 )
3085 {
3086 CHAR8 *Ip6Str;
3087 UINTN StringSize;
3088 CHAR8 *PrefixStr;
3089 CHAR8 *TempStr;
3090 EFI_STATUS Status;
3091 UINT8 Length;
3092
3093 if ((String == NULL) || (Ip6Address == NULL) || (PrefixLength == NULL)) {
3094 return EFI_INVALID_PARAMETER;
3095 }
3096
3097 StringSize = StrLen (String) + 1;
3098 Ip6Str = (CHAR8 *) AllocatePool (StringSize * sizeof (CHAR8));
3099 if (Ip6Str == NULL) {
3100 return EFI_OUT_OF_RESOURCES;
3101 }
3102
3103 UnicodeStrToAsciiStrS (String, Ip6Str, StringSize);
3104
3105 //
3106 // Get the sub string describing prefix length.
3107 //
3108 TempStr = Ip6Str;
3109 while (*TempStr != '\0' && (*TempStr != '/')) {
3110 TempStr++;
3111 }
3112
3113 if (*TempStr == '/') {
3114 PrefixStr = TempStr + 1;
3115 } else {
3116 PrefixStr = NULL;
3117 }
3118
3119 //
3120 // Get the sub string describing IPv6 address and convert it.
3121 //
3122 *TempStr = '\0';
3123
3124 Status = NetLibAsciiStrToIp6 (Ip6Str, Ip6Address);
3125 if (EFI_ERROR (Status)) {
3126 goto Exit;
3127 }
3128
3129 //
3130 // If input string doesn't indicate the prefix length, return 0xff.
3131 //
3132 Length = 0xFF;
3133
3134 //
3135 // Convert the string to prefix length
3136 //
3137 if (PrefixStr != NULL) {
3138
3139 Status = EFI_INVALID_PARAMETER;
3140 Length = 0;
3141 while (*PrefixStr != '\0') {
3142 if (NET_IS_DIGIT (*PrefixStr)) {
3143 Length = (UINT8) (Length * 10 + (*PrefixStr - '0'));
3144 if (Length > IP6_PREFIX_MAX) {
3145 goto Exit;
3146 }
3147 } else {
3148 goto Exit;
3149 }
3150
3151 PrefixStr++;
3152 }
3153 }
3154
3155 *PrefixLength = Length;
3156 Status = EFI_SUCCESS;
3157
3158 Exit:
3159
3160 FreePool (Ip6Str);
3161 return Status;
3162 }
3163
3164 /**
3165
3166 Convert one EFI_IPv6_ADDRESS to Null-terminated Unicode string.
3167 The text representation of address is defined in RFC 4291.
3168
3169 @param[in] Ip6Address The pointer to the IPv6 address.
3170 @param[out] String The buffer to return the converted string.
3171 @param[in] StringSize The length in bytes of the input String.
3172
3173 @retval EFI_SUCCESS Convert to string successfully.
3174 @retval EFI_INVALID_PARAMETER The input parameter is invalid.
3175 @retval EFI_BUFFER_TOO_SMALL The BufferSize is too small for the result. BufferSize has been
3176 updated with the size needed to complete the request.
3177 **/
3178 EFI_STATUS
3179 EFIAPI
NetLibIp6ToStr(IN EFI_IPv6_ADDRESS * Ip6Address,OUT CHAR16 * String,IN UINTN StringSize)3180 NetLibIp6ToStr (
3181 IN EFI_IPv6_ADDRESS *Ip6Address,
3182 OUT CHAR16 *String,
3183 IN UINTN StringSize
3184 )
3185 {
3186 UINT16 Ip6Addr[8];
3187 UINTN Index;
3188 UINTN LongestZerosStart;
3189 UINTN LongestZerosLength;
3190 UINTN CurrentZerosStart;
3191 UINTN CurrentZerosLength;
3192 CHAR16 Buffer[sizeof"ffff:ffff:ffff:ffff:ffff:ffff:ffff:ffff"];
3193 CHAR16 *Ptr;
3194
3195 if (Ip6Address == NULL || String == NULL || StringSize == 0) {
3196 return EFI_INVALID_PARAMETER;
3197 }
3198
3199 //
3200 // Convert the UINT8 array to an UINT16 array for easy handling.
3201 //
3202 ZeroMem (Ip6Addr, sizeof (Ip6Addr));
3203 for (Index = 0; Index < 16; Index++) {
3204 Ip6Addr[Index / 2] |= (Ip6Address->Addr[Index] << ((1 - (Index % 2)) << 3));
3205 }
3206
3207 //
3208 // Find the longest zeros and mark it.
3209 //
3210 CurrentZerosStart = DEFAULT_ZERO_START;
3211 CurrentZerosLength = 0;
3212 LongestZerosStart = DEFAULT_ZERO_START;
3213 LongestZerosLength = 0;
3214 for (Index = 0; Index < 8; Index++) {
3215 if (Ip6Addr[Index] == 0) {
3216 if (CurrentZerosStart == DEFAULT_ZERO_START) {
3217 CurrentZerosStart = Index;
3218 CurrentZerosLength = 1;
3219 } else {
3220 CurrentZerosLength++;
3221 }
3222 } else {
3223 if (CurrentZerosStart != DEFAULT_ZERO_START) {
3224 if (CurrentZerosLength > 2 && (LongestZerosStart == (DEFAULT_ZERO_START) || CurrentZerosLength > LongestZerosLength)) {
3225 LongestZerosStart = CurrentZerosStart;
3226 LongestZerosLength = CurrentZerosLength;
3227 }
3228 CurrentZerosStart = DEFAULT_ZERO_START;
3229 CurrentZerosLength = 0;
3230 }
3231 }
3232 }
3233
3234 if (CurrentZerosStart != DEFAULT_ZERO_START && CurrentZerosLength > 2) {
3235 if (LongestZerosStart == DEFAULT_ZERO_START || LongestZerosLength < CurrentZerosLength) {
3236 LongestZerosStart = CurrentZerosStart;
3237 LongestZerosLength = CurrentZerosLength;
3238 }
3239 }
3240
3241 Ptr = Buffer;
3242 for (Index = 0; Index < 8; Index++) {
3243 if (LongestZerosStart != DEFAULT_ZERO_START && Index >= LongestZerosStart && Index < LongestZerosStart + LongestZerosLength) {
3244 if (Index == LongestZerosStart) {
3245 *Ptr++ = L':';
3246 }
3247 continue;
3248 }
3249 if (Index != 0) {
3250 *Ptr++ = L':';
3251 }
3252 Ptr += UnicodeSPrint(Ptr, 10, L"%x", Ip6Addr[Index]);
3253 }
3254
3255 if (LongestZerosStart != DEFAULT_ZERO_START && LongestZerosStart + LongestZerosLength == 8) {
3256 *Ptr++ = L':';
3257 }
3258 *Ptr = L'\0';
3259
3260 if ((UINTN)Ptr - (UINTN)Buffer > StringSize) {
3261 return EFI_BUFFER_TOO_SMALL;
3262 }
3263
3264 StrCpyS (String, StringSize / sizeof (CHAR16), Buffer);
3265
3266 return EFI_SUCCESS;
3267 }
3268
3269 /**
3270 This function obtains the system guid from the smbios table.
3271
3272 @param[out] SystemGuid The pointer of the returned system guid.
3273
3274 @retval EFI_SUCCESS Successfully obtained the system guid.
3275 @retval EFI_NOT_FOUND Did not find the SMBIOS table.
3276
3277 **/
3278 EFI_STATUS
3279 EFIAPI
NetLibGetSystemGuid(OUT EFI_GUID * SystemGuid)3280 NetLibGetSystemGuid (
3281 OUT EFI_GUID *SystemGuid
3282 )
3283 {
3284 EFI_STATUS Status;
3285 SMBIOS_TABLE_ENTRY_POINT *SmbiosTable;
3286 SMBIOS_TABLE_3_0_ENTRY_POINT *Smbios30Table;
3287 SMBIOS_STRUCTURE_POINTER Smbios;
3288 SMBIOS_STRUCTURE_POINTER SmbiosEnd;
3289 CHAR8 *String;
3290
3291 SmbiosTable = NULL;
3292 Status = EfiGetSystemConfigurationTable (&gEfiSmbios3TableGuid, (VOID **) &Smbios30Table);
3293 if (!(EFI_ERROR (Status) || Smbios30Table == NULL)) {
3294 Smbios.Hdr = (SMBIOS_STRUCTURE *) (UINTN) Smbios30Table->TableAddress;
3295 SmbiosEnd.Raw = (UINT8 *) (UINTN) (Smbios30Table->TableAddress + Smbios30Table->TableMaximumSize);
3296 } else {
3297 Status = EfiGetSystemConfigurationTable (&gEfiSmbiosTableGuid, (VOID **) &SmbiosTable);
3298 if (EFI_ERROR (Status) || SmbiosTable == NULL) {
3299 return EFI_NOT_FOUND;
3300 }
3301 Smbios.Hdr = (SMBIOS_STRUCTURE *) (UINTN) SmbiosTable->TableAddress;
3302 SmbiosEnd.Raw = (UINT8 *) (UINTN) (SmbiosTable->TableAddress + SmbiosTable->TableLength);
3303 }
3304
3305 do {
3306 if (Smbios.Hdr->Type == 1) {
3307 if (Smbios.Hdr->Length < 0x19) {
3308 //
3309 // Older version did not support UUID.
3310 //
3311 return EFI_NOT_FOUND;
3312 }
3313
3314 //
3315 // SMBIOS tables are byte packed so we need to do a byte copy to
3316 // prevend alignment faults on Itanium-based platform.
3317 //
3318 CopyMem (SystemGuid, &Smbios.Type1->Uuid, sizeof (EFI_GUID));
3319 return EFI_SUCCESS;
3320 }
3321
3322 //
3323 // Go to the next SMBIOS structure. Each SMBIOS structure may include 2 parts:
3324 // 1. Formatted section; 2. Unformatted string section. So, 2 steps are needed
3325 // to skip one SMBIOS structure.
3326 //
3327
3328 //
3329 // Step 1: Skip over formatted section.
3330 //
3331 String = (CHAR8 *) (Smbios.Raw + Smbios.Hdr->Length);
3332
3333 //
3334 // Step 2: Skip over unformated string section.
3335 //
3336 do {
3337 //
3338 // Each string is terminated with a NULL(00h) BYTE and the sets of strings
3339 // is terminated with an additional NULL(00h) BYTE.
3340 //
3341 for ( ; *String != 0; String++) {
3342 }
3343
3344 if (*(UINT8*)++String == 0) {
3345 //
3346 // Pointer to the next SMBIOS structure.
3347 //
3348 Smbios.Raw = (UINT8 *)++String;
3349 break;
3350 }
3351 } while (TRUE);
3352 } while (Smbios.Raw < SmbiosEnd.Raw);
3353 return EFI_NOT_FOUND;
3354 }
3355
3356 /**
3357 Create Dns QName according the queried domain name.
3358 QName is a domain name represented as a sequence of labels,
3359 where each label consists of a length octet followed by that
3360 number of octets. The QName terminates with the zero
3361 length octet for the null label of the root. Caller should
3362 take responsibility to free the buffer in returned pointer.
3363
3364 @param DomainName The pointer to the queried domain name string.
3365
3366 @retval NULL Failed to fill QName.
3367 @return QName filled successfully.
3368
3369 **/
3370 CHAR8 *
3371 EFIAPI
NetLibCreateDnsQName(IN CHAR16 * DomainName)3372 NetLibCreateDnsQName (
3373 IN CHAR16 *DomainName
3374 )
3375 {
3376 CHAR8 *QueryName;
3377 UINTN QueryNameSize;
3378 CHAR8 *Header;
3379 CHAR8 *Tail;
3380 UINTN Len;
3381 UINTN Index;
3382
3383 QueryName = NULL;
3384 QueryNameSize = 0;
3385 Header = NULL;
3386 Tail = NULL;
3387
3388 //
3389 // One byte for first label length, one byte for terminated length zero.
3390 //
3391 QueryNameSize = StrLen (DomainName) + 2;
3392
3393 if (QueryNameSize > DNS_MAX_NAME_SIZE) {
3394 return NULL;
3395 }
3396
3397 QueryName = AllocateZeroPool (QueryNameSize);
3398 if (QueryName == NULL) {
3399 return NULL;
3400 }
3401
3402 Header = QueryName;
3403 Tail = Header + 1;
3404 Len = 0;
3405 for (Index = 0; DomainName[Index] != 0; Index++) {
3406 *Tail = (CHAR8) DomainName[Index];
3407 if (*Tail == '.') {
3408 *Header = (CHAR8) Len;
3409 Header = Tail;
3410 Tail ++;
3411 Len = 0;
3412 } else {
3413 Tail++;
3414 Len++;
3415 }
3416 }
3417 *Header = (CHAR8) Len;
3418 *Tail = 0;
3419
3420 return QueryName;
3421 }
3422