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da1d0201 | 1 | /** @file\r |
3e7104c2 | 2 | Network library.\r |
1204fe83 | 3 | \r |
6879581d | 4 | Copyright (c) 2005 - 2013, Intel Corporation. All rights reserved.<BR>\r |
cd5ebaa0 | 5 | This program and the accompanying materials\r |
da1d0201 | 6 | are licensed and made available under the terms and conditions of the BSD License\r |
7 | which accompanies this distribution. The full text of the license may be found at\r | |
8 | http://opensource.org/licenses/bsd-license.php\r | |
9 | \r | |
10 | THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,\r | |
11 | WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.\r | |
da1d0201 | 12 | **/\r |
13 | \r | |
3e7104c2 | 14 | #include <Uefi.h>\r |
da1d0201 | 15 | \r |
57b301b5 | 16 | #include <IndustryStandard/SmBios.h>\r |
17 | \r | |
752ef5d8 | 18 | #include <Protocol/DriverBinding.h>\r |
da1d0201 | 19 | #include <Protocol/ServiceBinding.h>\r |
20 | #include <Protocol/SimpleNetwork.h>\r | |
1204fe83 | 21 | #include <Protocol/ManagedNetwork.h>\r |
63886849 | 22 | #include <Protocol/HiiConfigRouting.h>\r |
3012ce5c | 23 | #include <Protocol/ComponentName.h>\r |
24 | #include <Protocol/ComponentName2.h>\r | |
1dc1b43f | 25 | #include <Protocol/HiiConfigAccess.h>\r |
da1d0201 | 26 | \r |
63886849 | 27 | #include <Guid/NicIp4ConfigNvData.h>\r |
57b301b5 | 28 | #include <Guid/SmBios.h>\r |
63886849 | 29 | \r |
da1d0201 | 30 | #include <Library/NetLib.h>\r |
31 | #include <Library/BaseLib.h>\r | |
32 | #include <Library/DebugLib.h>\r | |
33 | #include <Library/BaseMemoryLib.h>\r | |
34 | #include <Library/UefiBootServicesTableLib.h>\r | |
35 | #include <Library/UefiRuntimeServicesTableLib.h>\r | |
da1d0201 | 36 | #include <Library/MemoryAllocationLib.h>\r |
1232b214 | 37 | #include <Library/DevicePathLib.h>\r |
63886849 | 38 | #include <Library/HiiLib.h>\r |
39 | #include <Library/PrintLib.h>\r | |
1dc1b43f | 40 | #include <Library/UefiLib.h>\r |
da1d0201 | 41 | \r |
ce4106be | 42 | #define NIC_ITEM_CONFIG_SIZE sizeof (NIC_IP4_CONFIG_INFO) + sizeof (EFI_IP4_ROUTE_TABLE) * MAX_IP4_CONFIG_IN_VARIABLE\r |
216f7970 | 43 | #define DEFAULT_ZERO_START ((UINTN) ~0)\r |
63886849 | 44 | \r |
da1d0201 | 45 | //\r |
46 | // All the supported IP4 maskes in host byte order.\r | |
47 | //\r | |
1204fe83 | 48 | GLOBAL_REMOVE_IF_UNREFERENCED IP4_ADDR gIp4AllMasks[IP4_MASK_NUM] = {\r |
da1d0201 | 49 | 0x00000000,\r |
50 | 0x80000000,\r | |
51 | 0xC0000000,\r | |
52 | 0xE0000000,\r | |
53 | 0xF0000000,\r | |
54 | 0xF8000000,\r | |
55 | 0xFC000000,\r | |
56 | 0xFE000000,\r | |
57 | \r | |
58 | 0xFF000000,\r | |
59 | 0xFF800000,\r | |
60 | 0xFFC00000,\r | |
61 | 0xFFE00000,\r | |
62 | 0xFFF00000,\r | |
63 | 0xFFF80000,\r | |
64 | 0xFFFC0000,\r | |
65 | 0xFFFE0000,\r | |
66 | \r | |
67 | 0xFFFF0000,\r | |
68 | 0xFFFF8000,\r | |
69 | 0xFFFFC000,\r | |
70 | 0xFFFFE000,\r | |
71 | 0xFFFFF000,\r | |
72 | 0xFFFFF800,\r | |
73 | 0xFFFFFC00,\r | |
74 | 0xFFFFFE00,\r | |
75 | \r | |
76 | 0xFFFFFF00,\r | |
77 | 0xFFFFFF80,\r | |
78 | 0xFFFFFFC0,\r | |
79 | 0xFFFFFFE0,\r | |
80 | 0xFFFFFFF0,\r | |
81 | 0xFFFFFFF8,\r | |
82 | 0xFFFFFFFC,\r | |
83 | 0xFFFFFFFE,\r | |
84 | 0xFFFFFFFF,\r | |
85 | };\r | |
86 | \r | |
1204fe83 | 87 | GLOBAL_REMOVE_IF_UNREFERENCED EFI_IPv4_ADDRESS mZeroIp4Addr = {{0, 0, 0, 0}};\r |
da1d0201 | 88 | \r |
f6b7393c | 89 | //\r |
1204fe83 | 90 | // Any error level digitally larger than mNetDebugLevelMax\r |
f6b7393c | 91 | // will be silently discarded.\r |
92 | //\r | |
1204fe83 | 93 | GLOBAL_REMOVE_IF_UNREFERENCED UINTN mNetDebugLevelMax = NETDEBUG_LEVEL_ERROR;\r |
94 | GLOBAL_REMOVE_IF_UNREFERENCED UINT32 mSyslogPacketSeq = 0xDEADBEEF;\r | |
f6b7393c | 95 | \r |
f6b7393c | 96 | //\r |
1204fe83 | 97 | // You can change mSyslogDstMac mSyslogDstIp and mSyslogSrcIp\r |
98 | // here to direct the syslog packets to the syslog deamon. The\r | |
99 | // default is broadcast to both the ethernet and IP.\r | |
100 | //\r | |
101 | GLOBAL_REMOVE_IF_UNREFERENCED UINT8 mSyslogDstMac[NET_ETHER_ADDR_LEN] = {0xff, 0xff, 0xff, 0xff, 0xff, 0xff};\r | |
102 | GLOBAL_REMOVE_IF_UNREFERENCED UINT32 mSyslogDstIp = 0xffffffff;\r | |
103 | GLOBAL_REMOVE_IF_UNREFERENCED UINT32 mSyslogSrcIp = 0;\r | |
f6b7393c | 104 | \r |
1204fe83 | 105 | GLOBAL_REMOVE_IF_UNREFERENCED CHAR8 *mMonthName[] = {\r |
f6b7393c | 106 | "Jan",\r |
107 | "Feb",\r | |
108 | "Mar",\r | |
109 | "Apr",\r | |
110 | "May",\r | |
111 | "Jun",\r | |
112 | "Jul",\r | |
113 | "Aug",\r | |
114 | "Sep",\r | |
115 | "Oct",\r | |
116 | "Nov",\r | |
117 | "Dec"\r | |
118 | };\r | |
119 | \r | |
779ae357 | 120 | //\r |
121 | // VLAN device path node template\r | |
122 | //\r | |
123 | GLOBAL_REMOVE_IF_UNREFERENCED VLAN_DEVICE_PATH mNetVlanDevicePathTemplate = {\r | |
124 | {\r | |
125 | MESSAGING_DEVICE_PATH,\r | |
126 | MSG_VLAN_DP,\r | |
127 | {\r | |
128 | (UINT8) (sizeof (VLAN_DEVICE_PATH)),\r | |
129 | (UINT8) ((sizeof (VLAN_DEVICE_PATH)) >> 8)\r | |
130 | }\r | |
131 | },\r | |
132 | 0\r | |
133 | };\r | |
134 | \r | |
f6b7393c | 135 | /**\r |
1204fe83 | 136 | Locate the handles that support SNP, then open one of them\r |
f6b7393c | 137 | to send the syslog packets. The caller isn't required to close\r |
138 | the SNP after use because the SNP is opened by HandleProtocol.\r | |
139 | \r | |
140 | @return The point to SNP if one is properly openned. Otherwise NULL\r | |
141 | \r | |
142 | **/\r | |
143 | EFI_SIMPLE_NETWORK_PROTOCOL *\r | |
144 | SyslogLocateSnp (\r | |
145 | VOID\r | |
146 | )\r | |
147 | {\r | |
148 | EFI_SIMPLE_NETWORK_PROTOCOL *Snp;\r | |
149 | EFI_STATUS Status;\r | |
150 | EFI_HANDLE *Handles;\r | |
151 | UINTN HandleCount;\r | |
152 | UINTN Index;\r | |
153 | \r | |
154 | //\r | |
155 | // Locate the handles which has SNP installed.\r | |
156 | //\r | |
157 | Handles = NULL;\r | |
158 | Status = gBS->LocateHandleBuffer (\r | |
159 | ByProtocol,\r | |
160 | &gEfiSimpleNetworkProtocolGuid,\r | |
161 | NULL,\r | |
162 | &HandleCount,\r | |
163 | &Handles\r | |
164 | );\r | |
165 | \r | |
166 | if (EFI_ERROR (Status) || (HandleCount == 0)) {\r | |
167 | return NULL;\r | |
168 | }\r | |
1204fe83 | 169 | \r |
f6b7393c | 170 | //\r |
171 | // Try to open one of the ethernet SNP protocol to send packet\r | |
172 | //\r | |
173 | Snp = NULL;\r | |
1204fe83 | 174 | \r |
f6b7393c | 175 | for (Index = 0; Index < HandleCount; Index++) {\r |
176 | Status = gBS->HandleProtocol (\r | |
177 | Handles[Index],\r | |
178 | &gEfiSimpleNetworkProtocolGuid,\r | |
179 | (VOID **) &Snp\r | |
180 | );\r | |
181 | \r | |
1204fe83 | 182 | if ((Status == EFI_SUCCESS) && (Snp != NULL) &&\r |
f6b7393c | 183 | (Snp->Mode->IfType == NET_IFTYPE_ETHERNET) &&\r |
184 | (Snp->Mode->MaxPacketSize >= NET_SYSLOG_PACKET_LEN)) {\r | |
1204fe83 | 185 | \r |
f6b7393c | 186 | break;\r |
187 | }\r | |
188 | \r | |
189 | Snp = NULL;\r | |
190 | }\r | |
191 | \r | |
ad108abe | 192 | FreePool (Handles);\r |
f6b7393c | 193 | return Snp;\r |
194 | }\r | |
195 | \r | |
196 | /**\r | |
197 | Transmit a syslog packet synchronously through SNP. The Packet\r | |
1204fe83 | 198 | already has the ethernet header prepended. This function should\r |
f6b7393c | 199 | fill in the source MAC because it will try to locate a SNP each\r |
200 | time it is called to avoid the problem if SNP is unloaded.\r | |
1204fe83 | 201 | This code snip is copied from MNP.\r |
202 | \r | |
203 | @param[in] Packet The Syslog packet\r | |
204 | @param[in] Length The length of the packet\r | |
f6b7393c | 205 | \r |
1204fe83 | 206 | @retval EFI_DEVICE_ERROR Failed to locate a usable SNP protocol\r |
207 | @retval EFI_TIMEOUT Timeout happened to send the packet.\r | |
208 | @retval EFI_SUCCESS Packet is sent.\r | |
f6b7393c | 209 | \r |
f6b7393c | 210 | **/\r |
211 | EFI_STATUS\r | |
212 | SyslogSendPacket (\r | |
213 | IN CHAR8 *Packet,\r | |
214 | IN UINT32 Length\r | |
215 | )\r | |
216 | {\r | |
217 | EFI_SIMPLE_NETWORK_PROTOCOL *Snp;\r | |
218 | ETHER_HEAD *Ether;\r | |
219 | EFI_STATUS Status;\r | |
220 | EFI_EVENT TimeoutEvent;\r | |
221 | UINT8 *TxBuf;\r | |
222 | \r | |
223 | Snp = SyslogLocateSnp ();\r | |
224 | \r | |
225 | if (Snp == NULL) {\r | |
226 | return EFI_DEVICE_ERROR;\r | |
227 | }\r | |
228 | \r | |
229 | Ether = (ETHER_HEAD *) Packet;\r | |
230 | CopyMem (Ether->SrcMac, Snp->Mode->CurrentAddress.Addr, NET_ETHER_ADDR_LEN);\r | |
231 | \r | |
232 | //\r | |
233 | // Start the timeout event.\r | |
234 | //\r | |
235 | Status = gBS->CreateEvent (\r | |
236 | EVT_TIMER,\r | |
237 | TPL_NOTIFY,\r | |
238 | NULL,\r | |
239 | NULL,\r | |
240 | &TimeoutEvent\r | |
241 | );\r | |
242 | \r | |
243 | if (EFI_ERROR (Status)) {\r | |
244 | return Status;\r | |
245 | }\r | |
246 | \r | |
247 | Status = gBS->SetTimer (TimeoutEvent, TimerRelative, NET_SYSLOG_TX_TIMEOUT);\r | |
248 | \r | |
249 | if (EFI_ERROR (Status)) {\r | |
250 | goto ON_EXIT;\r | |
251 | }\r | |
252 | \r | |
253 | for (;;) {\r | |
254 | //\r | |
255 | // Transmit the packet through SNP.\r | |
256 | //\r | |
257 | Status = Snp->Transmit (Snp, 0, Length, Packet, NULL, NULL, NULL);\r | |
258 | \r | |
259 | if ((Status != EFI_SUCCESS) && (Status != EFI_NOT_READY)) {\r | |
260 | Status = EFI_DEVICE_ERROR;\r | |
261 | break;\r | |
262 | }\r | |
1204fe83 | 263 | \r |
f6b7393c | 264 | //\r |
265 | // If Status is EFI_SUCCESS, the packet is put in the transmit queue.\r | |
266 | // if Status is EFI_NOT_READY, the transmit engine of the network\r | |
267 | // interface is busy. Both need to sync SNP.\r | |
268 | //\r | |
269 | TxBuf = NULL;\r | |
270 | \r | |
271 | do {\r | |
272 | //\r | |
273 | // Get the recycled transmit buffer status.\r | |
274 | //\r | |
275 | Snp->GetStatus (Snp, NULL, (VOID **) &TxBuf);\r | |
276 | \r | |
277 | if (!EFI_ERROR (gBS->CheckEvent (TimeoutEvent))) {\r | |
278 | Status = EFI_TIMEOUT;\r | |
279 | break;\r | |
280 | }\r | |
281 | \r | |
282 | } while (TxBuf == NULL);\r | |
283 | \r | |
284 | if ((Status == EFI_SUCCESS) || (Status == EFI_TIMEOUT)) {\r | |
285 | break;\r | |
286 | }\r | |
1204fe83 | 287 | \r |
f6b7393c | 288 | //\r |
289 | // Status is EFI_NOT_READY. Restart the timer event and\r | |
290 | // call Snp->Transmit again.\r | |
291 | //\r | |
292 | gBS->SetTimer (TimeoutEvent, TimerRelative, NET_SYSLOG_TX_TIMEOUT);\r | |
293 | }\r | |
294 | \r | |
295 | gBS->SetTimer (TimeoutEvent, TimerCancel, 0);\r | |
296 | \r | |
297 | ON_EXIT:\r | |
298 | gBS->CloseEvent (TimeoutEvent);\r | |
299 | return Status;\r | |
300 | }\r | |
301 | \r | |
302 | /**\r | |
1204fe83 | 303 | Build a syslog packet, including the Ethernet/Ip/Udp headers\r |
304 | and user's message.\r | |
f6b7393c | 305 | \r |
1204fe83 | 306 | @param[in] Level Syslog servity level\r |
307 | @param[in] Module The module that generates the log\r | |
308 | @param[in] File The file that contains the current log\r | |
309 | @param[in] Line The line of code in the File that contains the current log\r | |
310 | @param[in] Message The log message\r | |
311 | @param[in] BufLen The lenght of the Buf\r | |
312 | @param[out] Buf The buffer to put the packet data\r | |
f6b7393c | 313 | \r |
1204fe83 | 314 | @return The length of the syslog packet built.\r |
f6b7393c | 315 | \r |
316 | **/\r | |
317 | UINT32\r | |
318 | SyslogBuildPacket (\r | |
319 | IN UINT32 Level,\r | |
320 | IN UINT8 *Module,\r | |
321 | IN UINT8 *File,\r | |
322 | IN UINT32 Line,\r | |
323 | IN UINT8 *Message,\r | |
324 | IN UINT32 BufLen,\r | |
1204fe83 | 325 | OUT CHAR8 *Buf\r |
f6b7393c | 326 | )\r |
327 | {\r | |
328 | ETHER_HEAD *Ether;\r | |
329 | IP4_HEAD *Ip4;\r | |
330 | EFI_UDP_HEADER *Udp4;\r | |
331 | EFI_TIME Time;\r | |
332 | UINT32 Pri;\r | |
333 | UINT32 Len;\r | |
334 | \r | |
335 | //\r | |
1204fe83 | 336 | // Fill in the Ethernet header. Leave alone the source MAC.\r |
f6b7393c | 337 | // SyslogSendPacket will fill in the address for us.\r |
338 | //\r | |
339 | Ether = (ETHER_HEAD *) Buf;\r | |
340 | CopyMem (Ether->DstMac, mSyslogDstMac, NET_ETHER_ADDR_LEN);\r | |
341 | ZeroMem (Ether->SrcMac, NET_ETHER_ADDR_LEN);\r | |
342 | \r | |
343 | Ether->EtherType = HTONS (0x0800); // IPv4 protocol\r | |
344 | \r | |
345 | Buf += sizeof (ETHER_HEAD);\r | |
346 | BufLen -= sizeof (ETHER_HEAD);\r | |
347 | \r | |
348 | //\r | |
349 | // Fill in the IP header\r | |
350 | //\r | |
351 | Ip4 = (IP4_HEAD *) Buf;\r | |
352 | Ip4->HeadLen = 5;\r | |
353 | Ip4->Ver = 4;\r | |
354 | Ip4->Tos = 0;\r | |
355 | Ip4->TotalLen = 0;\r | |
356 | Ip4->Id = (UINT16) mSyslogPacketSeq;\r | |
357 | Ip4->Fragment = 0;\r | |
358 | Ip4->Ttl = 16;\r | |
359 | Ip4->Protocol = 0x11;\r | |
360 | Ip4->Checksum = 0;\r | |
361 | Ip4->Src = mSyslogSrcIp;\r | |
362 | Ip4->Dst = mSyslogDstIp;\r | |
363 | \r | |
364 | Buf += sizeof (IP4_HEAD);\r | |
365 | BufLen -= sizeof (IP4_HEAD);\r | |
366 | \r | |
367 | //\r | |
368 | // Fill in the UDP header, Udp checksum is optional. Leave it zero.\r | |
369 | //\r | |
370 | Udp4 = (EFI_UDP_HEADER *) Buf;\r | |
371 | Udp4->SrcPort = HTONS (514);\r | |
372 | Udp4->DstPort = HTONS (514);\r | |
373 | Udp4->Length = 0;\r | |
374 | Udp4->Checksum = 0;\r | |
375 | \r | |
376 | Buf += sizeof (EFI_UDP_HEADER);\r | |
377 | BufLen -= sizeof (EFI_UDP_HEADER);\r | |
378 | \r | |
379 | //\r | |
380 | // Build the syslog message body with <PRI> Timestamp machine module Message\r | |
381 | //\r | |
382 | Pri = ((NET_SYSLOG_FACILITY & 31) << 3) | (Level & 7);\r | |
383 | gRT->GetTime (&Time, NULL);\r | |
95157291 | 384 | ASSERT ((Time.Month <= 12) && (Time.Month >= 1));\r |
f6b7393c | 385 | \r |
386 | //\r | |
387 | // Use %a to format the ASCII strings, %s to format UNICODE strings\r | |
388 | //\r | |
389 | Len = 0;\r | |
390 | Len += (UINT32) AsciiSPrint (\r | |
391 | Buf,\r | |
392 | BufLen,\r | |
393 | "<%d> %a %d %d:%d:%d ",\r | |
394 | Pri,\r | |
1204fe83 | 395 | mMonthName [Time.Month-1],\r |
f6b7393c | 396 | Time.Day,\r |
397 | Time.Hour,\r | |
398 | Time.Minute,\r | |
399 | Time.Second\r | |
400 | );\r | |
401 | Len--;\r | |
402 | \r | |
403 | Len += (UINT32) AsciiSPrint (\r | |
1204fe83 | 404 | Buf + Len,\r |
405 | BufLen - Len,\r | |
406 | "Tiano %a: %a (Line: %d File: %a)",\r | |
f6b7393c | 407 | Module,\r |
408 | Message,\r | |
409 | Line,\r | |
410 | File\r | |
411 | );\r | |
412 | Len--;\r | |
413 | \r | |
414 | //\r | |
415 | // OK, patch the IP length/checksum and UDP length fields.\r | |
416 | //\r | |
417 | Len += sizeof (EFI_UDP_HEADER);\r | |
418 | Udp4->Length = HTONS ((UINT16) Len);\r | |
419 | \r | |
420 | Len += sizeof (IP4_HEAD);\r | |
421 | Ip4->TotalLen = HTONS ((UINT16) Len);\r | |
422 | Ip4->Checksum = (UINT16) (~NetblockChecksum ((UINT8 *) Ip4, sizeof (IP4_HEAD)));\r | |
423 | \r | |
424 | return Len + sizeof (ETHER_HEAD);\r | |
425 | }\r | |
426 | \r | |
427 | /**\r | |
1204fe83 | 428 | Allocate a buffer, then format the message to it. This is a\r |
429 | help function for the NET_DEBUG_XXX macros. The PrintArg of\r | |
430 | these macros treats the variable length print parameters as a\r | |
f6b7393c | 431 | single parameter, and pass it to the NetDebugASPrint. For\r |
432 | example, NET_DEBUG_TRACE ("Tcp", ("State transit to %a\n", Name))\r | |
1204fe83 | 433 | if extracted to:\r |
434 | \r | |
f6b7393c | 435 | NetDebugOutput (\r |
1204fe83 | 436 | NETDEBUG_LEVEL_TRACE,\r |
437 | "Tcp",\r | |
f6b7393c | 438 | __FILE__,\r |
439 | __LINE__,\r | |
1204fe83 | 440 | NetDebugASPrint ("State transit to %a\n", Name)\r |
441 | )\r | |
442 | \r | |
f6b7393c | 443 | @param Format The ASCII format string.\r |
1204fe83 | 444 | @param ... The variable length parameter whose format is determined\r |
f6b7393c | 445 | by the Format string.\r |
446 | \r | |
447 | @return The buffer containing the formatted message,\r | |
448 | or NULL if failed to allocate memory.\r | |
449 | \r | |
450 | **/\r | |
451 | CHAR8 *\r | |
e798cd87 | 452 | EFIAPI\r |
f6b7393c | 453 | NetDebugASPrint (\r |
454 | IN CHAR8 *Format,\r | |
455 | ...\r | |
456 | )\r | |
457 | {\r | |
458 | VA_LIST Marker;\r | |
459 | CHAR8 *Buf;\r | |
460 | \r | |
461 | Buf = (CHAR8 *) AllocatePool (NET_DEBUG_MSG_LEN);\r | |
462 | \r | |
463 | if (Buf == NULL) {\r | |
464 | return NULL;\r | |
465 | }\r | |
466 | \r | |
467 | VA_START (Marker, Format);\r | |
468 | AsciiVSPrint (Buf, NET_DEBUG_MSG_LEN, Format, Marker);\r | |
469 | VA_END (Marker);\r | |
470 | \r | |
471 | return Buf;\r | |
472 | }\r | |
473 | \r | |
474 | /**\r | |
475 | Builds an UDP4 syslog packet and send it using SNP.\r | |
476 | \r | |
477 | This function will locate a instance of SNP then send the message through it.\r | |
478 | Because it isn't open the SNP BY_DRIVER, apply caution when using it.\r | |
479 | \r | |
480 | @param Level The servity level of the message.\r | |
481 | @param Module The Moudle that generates the log.\r | |
482 | @param File The file that contains the log.\r | |
483 | @param Line The exact line that contains the log.\r | |
484 | @param Message The user message to log.\r | |
485 | \r | |
486 | @retval EFI_INVALID_PARAMETER Any input parameter is invalid.\r | |
487 | @retval EFI_OUT_OF_RESOURCES Failed to allocate memory for the packet\r | |
1204fe83 | 488 | @retval EFI_SUCCESS The log is discard because that it is more verbose\r |
f6b7393c | 489 | than the mNetDebugLevelMax. Or, it has been sent out.\r |
1204fe83 | 490 | **/\r |
f6b7393c | 491 | EFI_STATUS\r |
e798cd87 | 492 | EFIAPI\r |
f6b7393c | 493 | NetDebugOutput (\r |
1204fe83 | 494 | IN UINT32 Level,\r |
f6b7393c | 495 | IN UINT8 *Module,\r |
496 | IN UINT8 *File,\r | |
497 | IN UINT32 Line,\r | |
498 | IN UINT8 *Message\r | |
499 | )\r | |
500 | {\r | |
501 | CHAR8 *Packet;\r | |
502 | UINT32 Len;\r | |
503 | EFI_STATUS Status;\r | |
504 | \r | |
505 | //\r | |
506 | // Check whether the message should be sent out\r | |
507 | //\r | |
508 | if (Message == NULL) {\r | |
509 | return EFI_INVALID_PARAMETER;\r | |
510 | }\r | |
511 | \r | |
512 | if (Level > mNetDebugLevelMax) {\r | |
513 | Status = EFI_SUCCESS;\r | |
514 | goto ON_EXIT;\r | |
515 | }\r | |
1204fe83 | 516 | \r |
f6b7393c | 517 | //\r |
518 | // Allocate a maxium of 1024 bytes, the caller should ensure\r | |
519 | // that the message plus the ethernet/ip/udp header is shorter\r | |
520 | // than this\r | |
521 | //\r | |
522 | Packet = (CHAR8 *) AllocatePool (NET_SYSLOG_PACKET_LEN);\r | |
523 | \r | |
524 | if (Packet == NULL) {\r | |
525 | Status = EFI_OUT_OF_RESOURCES;\r | |
526 | goto ON_EXIT;\r | |
527 | }\r | |
1204fe83 | 528 | \r |
f6b7393c | 529 | //\r |
530 | // Build the message: Ethernet header + IP header + Udp Header + user data\r | |
531 | //\r | |
532 | Len = SyslogBuildPacket (\r | |
533 | Level,\r | |
534 | Module,\r | |
535 | File,\r | |
536 | Line,\r | |
537 | Message,\r | |
538 | NET_SYSLOG_PACKET_LEN,\r | |
539 | Packet\r | |
540 | );\r | |
541 | \r | |
542 | mSyslogPacketSeq++;\r | |
543 | Status = SyslogSendPacket (Packet, Len);\r | |
544 | FreePool (Packet);\r | |
545 | \r | |
546 | ON_EXIT:\r | |
547 | FreePool (Message);\r | |
548 | return Status;\r | |
549 | }\r | |
da1d0201 | 550 | /**\r |
1204fe83 | 551 | Return the length of the mask.\r |
552 | \r | |
b9008c87 | 553 | Return the length of the mask, the correct value is from 0 to 32.\r |
554 | If the mask is invalid, return the invalid length 33, which is IP4_MASK_NUM.\r | |
da1d0201 | 555 | NetMask is in the host byte order.\r |
556 | \r | |
3e7104c2 | 557 | @param[in] NetMask The netmask to get the length from.\r |
da1d0201 | 558 | \r |
b9008c87 | 559 | @return The length of the netmask, IP4_MASK_NUM if the mask is invalid.\r |
1204fe83 | 560 | \r |
da1d0201 | 561 | **/\r |
562 | INTN\r | |
7b414b4e | 563 | EFIAPI\r |
da1d0201 | 564 | NetGetMaskLength (\r |
565 | IN IP4_ADDR NetMask\r | |
566 | )\r | |
567 | {\r | |
568 | INTN Index;\r | |
569 | \r | |
570 | for (Index = 0; Index < IP4_MASK_NUM; Index++) {\r | |
2a86ff1c | 571 | if (NetMask == gIp4AllMasks[Index]) {\r |
da1d0201 | 572 | break;\r |
573 | }\r | |
574 | }\r | |
575 | \r | |
576 | return Index;\r | |
577 | }\r | |
578 | \r | |
579 | \r | |
580 | \r | |
581 | /**\r | |
b9008c87 | 582 | Return the class of the IP address, such as class A, B, C.\r |
da1d0201 | 583 | Addr is in host byte order.\r |
1204fe83 | 584 | \r |
b9008c87 | 585 | The address of class A starts with 0.\r |
586 | If the address belong to class A, return IP4_ADDR_CLASSA.\r | |
1204fe83 | 587 | The address of class B starts with 10.\r |
b9008c87 | 588 | If the address belong to class B, return IP4_ADDR_CLASSB.\r |
1204fe83 | 589 | The address of class C starts with 110.\r |
b9008c87 | 590 | If the address belong to class C, return IP4_ADDR_CLASSC.\r |
1204fe83 | 591 | The address of class D starts with 1110.\r |
b9008c87 | 592 | If the address belong to class D, return IP4_ADDR_CLASSD.\r |
593 | The address of class E starts with 1111.\r | |
594 | If the address belong to class E, return IP4_ADDR_CLASSE.\r | |
da1d0201 | 595 | \r |
1204fe83 | 596 | \r |
3e7104c2 | 597 | @param[in] Addr The address to get the class from.\r |
da1d0201 | 598 | \r |
3e7104c2 | 599 | @return IP address class, such as IP4_ADDR_CLASSA.\r |
da1d0201 | 600 | \r |
601 | **/\r | |
602 | INTN\r | |
7b414b4e | 603 | EFIAPI\r |
da1d0201 | 604 | NetGetIpClass (\r |
605 | IN IP4_ADDR Addr\r | |
606 | )\r | |
607 | {\r | |
608 | UINT8 ByteOne;\r | |
609 | \r | |
610 | ByteOne = (UINT8) (Addr >> 24);\r | |
611 | \r | |
612 | if ((ByteOne & 0x80) == 0) {\r | |
613 | return IP4_ADDR_CLASSA;\r | |
614 | \r | |
615 | } else if ((ByteOne & 0xC0) == 0x80) {\r | |
616 | return IP4_ADDR_CLASSB;\r | |
617 | \r | |
618 | } else if ((ByteOne & 0xE0) == 0xC0) {\r | |
619 | return IP4_ADDR_CLASSC;\r | |
620 | \r | |
621 | } else if ((ByteOne & 0xF0) == 0xE0) {\r | |
622 | return IP4_ADDR_CLASSD;\r | |
623 | \r | |
624 | } else {\r | |
625 | return IP4_ADDR_CLASSE;\r | |
626 | \r | |
627 | }\r | |
628 | }\r | |
629 | \r | |
630 | \r | |
631 | /**\r | |
632 | Check whether the IP is a valid unicast address according to\r | |
b9008c87 | 633 | the netmask. If NetMask is zero, use the IP address's class to get the default mask.\r |
1204fe83 | 634 | \r |
b9008c87 | 635 | If Ip is 0, IP is not a valid unicast address.\r |
636 | Class D address is used for multicasting and class E address is reserved for future. If Ip\r | |
1204fe83 | 637 | belongs to class D or class E, IP is not a valid unicast address.\r |
b9008c87 | 638 | If all bits of the host address of IP are 0 or 1, IP is also not a valid unicast address.\r |
da1d0201 | 639 | \r |
3e7104c2 | 640 | @param[in] Ip The IP to check against.\r |
641 | @param[in] NetMask The mask of the IP.\r | |
da1d0201 | 642 | \r |
3e7104c2 | 643 | @return TRUE if IP is a valid unicast address on the network, otherwise FALSE.\r |
da1d0201 | 644 | \r |
645 | **/\r | |
646 | BOOLEAN\r | |
7b414b4e | 647 | EFIAPI\r |
f6b7393c | 648 | NetIp4IsUnicast (\r |
da1d0201 | 649 | IN IP4_ADDR Ip,\r |
650 | IN IP4_ADDR NetMask\r | |
651 | )\r | |
652 | {\r | |
653 | INTN Class;\r | |
654 | \r | |
655 | Class = NetGetIpClass (Ip);\r | |
656 | \r | |
657 | if ((Ip == 0) || (Class >= IP4_ADDR_CLASSD)) {\r | |
658 | return FALSE;\r | |
659 | }\r | |
660 | \r | |
661 | if (NetMask == 0) {\r | |
2a86ff1c | 662 | NetMask = gIp4AllMasks[Class << 3];\r |
da1d0201 | 663 | }\r |
664 | \r | |
665 | if (((Ip &~NetMask) == ~NetMask) || ((Ip &~NetMask) == 0)) {\r | |
666 | return FALSE;\r | |
667 | }\r | |
668 | \r | |
669 | return TRUE;\r | |
670 | }\r | |
671 | \r | |
fb115c61 | 672 | /**\r |
673 | Check whether the incoming IPv6 address is a valid unicast address.\r | |
674 | \r | |
675 | If the address is a multicast address has binary 0xFF at the start, it is not\r | |
676 | a valid unicast address. If the address is unspecified ::, it is not a valid\r | |
677 | unicast address to be assigned to any node. If the address is loopback address\r | |
678 | ::1, it is also not a valid unicast address to be assigned to any physical\r | |
1204fe83 | 679 | interface.\r |
fb115c61 | 680 | \r |
681 | @param[in] Ip6 The IPv6 address to check against.\r | |
682 | \r | |
683 | @return TRUE if Ip6 is a valid unicast address on the network, otherwise FALSE.\r | |
684 | \r | |
1204fe83 | 685 | **/\r |
fb115c61 | 686 | BOOLEAN\r |
e798cd87 | 687 | EFIAPI\r |
f6b7393c | 688 | NetIp6IsValidUnicast (\r |
fb115c61 | 689 | IN EFI_IPv6_ADDRESS *Ip6\r |
1204fe83 | 690 | )\r |
fb115c61 | 691 | {\r |
b45b45b2 | 692 | UINT8 Byte;\r |
693 | UINT8 Index;\r | |
1204fe83 | 694 | \r |
fb115c61 | 695 | if (Ip6->Addr[0] == 0xFF) {\r |
696 | return FALSE;\r | |
697 | }\r | |
698 | \r | |
b45b45b2 | 699 | for (Index = 0; Index < 15; Index++) {\r |
700 | if (Ip6->Addr[Index] != 0) {\r | |
fb115c61 | 701 | return TRUE;\r |
702 | }\r | |
703 | }\r | |
704 | \r | |
b45b45b2 | 705 | Byte = Ip6->Addr[Index];\r |
fb115c61 | 706 | \r |
b45b45b2 | 707 | if (Byte == 0x0 || Byte == 0x1) {\r |
fb115c61 | 708 | return FALSE;\r |
709 | }\r | |
710 | \r | |
1204fe83 | 711 | return TRUE;\r |
fb115c61 | 712 | }\r |
da1d0201 | 713 | \r |
f6b7393c | 714 | /**\r |
715 | Check whether the incoming Ipv6 address is the unspecified address or not.\r | |
716 | \r | |
717 | @param[in] Ip6 - Ip6 address, in network order.\r | |
718 | \r | |
719 | @retval TRUE - Yes, unspecified\r | |
720 | @retval FALSE - No\r | |
1204fe83 | 721 | \r |
f6b7393c | 722 | **/\r |
723 | BOOLEAN\r | |
e798cd87 | 724 | EFIAPI\r |
f6b7393c | 725 | NetIp6IsUnspecifiedAddr (\r |
726 | IN EFI_IPv6_ADDRESS *Ip6\r | |
727 | )\r | |
728 | {\r | |
729 | UINT8 Index;\r | |
730 | \r | |
731 | for (Index = 0; Index < 16; Index++) {\r | |
732 | if (Ip6->Addr[Index] != 0) {\r | |
733 | return FALSE;\r | |
734 | }\r | |
735 | }\r | |
736 | \r | |
737 | return TRUE;\r | |
738 | }\r | |
739 | \r | |
740 | /**\r | |
741 | Check whether the incoming Ipv6 address is a link-local address.\r | |
742 | \r | |
743 | @param[in] Ip6 - Ip6 address, in network order.\r | |
744 | \r | |
745 | @retval TRUE - Yes, link-local address\r | |
746 | @retval FALSE - No\r | |
1204fe83 | 747 | \r |
f6b7393c | 748 | **/\r |
749 | BOOLEAN\r | |
e798cd87 | 750 | EFIAPI\r |
f6b7393c | 751 | NetIp6IsLinkLocalAddr (\r |
752 | IN EFI_IPv6_ADDRESS *Ip6\r | |
753 | )\r | |
754 | {\r | |
755 | UINT8 Index;\r | |
1204fe83 | 756 | \r |
f6b7393c | 757 | ASSERT (Ip6 != NULL);\r |
758 | \r | |
759 | if (Ip6->Addr[0] != 0xFE) {\r | |
760 | return FALSE;\r | |
761 | }\r | |
1204fe83 | 762 | \r |
f6b7393c | 763 | if (Ip6->Addr[1] != 0x80) {\r |
764 | return FALSE;\r | |
765 | }\r | |
766 | \r | |
767 | for (Index = 2; Index < 8; Index++) {\r | |
768 | if (Ip6->Addr[Index] != 0) {\r | |
769 | return FALSE;\r | |
770 | }\r | |
771 | }\r | |
772 | \r | |
773 | return TRUE;\r | |
774 | }\r | |
775 | \r | |
776 | /**\r | |
777 | Check whether the Ipv6 address1 and address2 are on the connected network.\r | |
778 | \r | |
779 | @param[in] Ip1 - Ip6 address1, in network order.\r | |
780 | @param[in] Ip2 - Ip6 address2, in network order.\r | |
781 | @param[in] PrefixLength - The prefix length of the checking net.\r | |
782 | \r | |
783 | @retval TRUE - Yes, connected.\r | |
784 | @retval FALSE - No.\r | |
1204fe83 | 785 | \r |
f6b7393c | 786 | **/\r |
787 | BOOLEAN\r | |
e798cd87 | 788 | EFIAPI\r |
f6b7393c | 789 | NetIp6IsNetEqual (\r |
790 | EFI_IPv6_ADDRESS *Ip1,\r | |
791 | EFI_IPv6_ADDRESS *Ip2,\r | |
792 | UINT8 PrefixLength\r | |
793 | )\r | |
794 | {\r | |
795 | UINT8 Byte;\r | |
796 | UINT8 Bit;\r | |
797 | UINT8 Mask;\r | |
798 | \r | |
70b68990 | 799 | ASSERT ((Ip1 != NULL) && (Ip2 != NULL) && (PrefixLength < IP6_PREFIX_NUM));\r |
1204fe83 | 800 | \r |
f6b7393c | 801 | if (PrefixLength == 0) {\r |
802 | return TRUE;\r | |
803 | }\r | |
804 | \r | |
805 | Byte = (UINT8) (PrefixLength / 8);\r | |
806 | Bit = (UINT8) (PrefixLength % 8);\r | |
1204fe83 | 807 | \r |
f6b7393c | 808 | if (CompareMem (Ip1, Ip2, Byte) != 0) {\r |
809 | return FALSE;\r | |
810 | }\r | |
811 | \r | |
812 | if (Bit > 0) {\r | |
813 | Mask = (UINT8) (0xFF << (8 - Bit));\r | |
814 | \r | |
70b68990 | 815 | ASSERT (Byte < 16);\r |
f6b7393c | 816 | if ((Ip1->Addr[Byte] & Mask) != (Ip2->Addr[Byte] & Mask)) {\r |
817 | return FALSE;\r | |
1204fe83 | 818 | }\r |
f6b7393c | 819 | }\r |
1204fe83 | 820 | \r |
f6b7393c | 821 | return TRUE;\r |
822 | }\r | |
823 | \r | |
824 | \r | |
b45b45b2 | 825 | /**\r |
826 | Switches the endianess of an IPv6 address\r | |
827 | \r | |
828 | This function swaps the bytes in a 128-bit IPv6 address to switch the value\r | |
829 | from little endian to big endian or vice versa. The byte swapped value is\r | |
830 | returned.\r | |
831 | \r | |
832 | @param Ip6 Points to an IPv6 address\r | |
833 | \r | |
834 | @return The byte swapped IPv6 address.\r | |
835 | \r | |
836 | **/\r | |
837 | EFI_IPv6_ADDRESS *\r | |
e798cd87 | 838 | EFIAPI\r |
b45b45b2 | 839 | Ip6Swap128 (\r |
840 | EFI_IPv6_ADDRESS *Ip6\r | |
841 | )\r | |
842 | {\r | |
843 | UINT64 High;\r | |
844 | UINT64 Low;\r | |
845 | \r | |
846 | CopyMem (&High, Ip6, sizeof (UINT64));\r | |
847 | CopyMem (&Low, &Ip6->Addr[8], sizeof (UINT64));\r | |
848 | \r | |
849 | High = SwapBytes64 (High);\r | |
850 | Low = SwapBytes64 (Low);\r | |
851 | \r | |
852 | CopyMem (Ip6, &Low, sizeof (UINT64));\r | |
853 | CopyMem (&Ip6->Addr[8], &High, sizeof (UINT64));\r | |
854 | \r | |
855 | return Ip6;\r | |
856 | }\r | |
857 | \r | |
da1d0201 | 858 | /**\r |
859 | Initialize a random seed using current time.\r | |
1204fe83 | 860 | \r |
861 | Get current time first. Then initialize a random seed based on some basic\r | |
862 | mathematics operation on the hour, day, minute, second, nanosecond and year\r | |
b9008c87 | 863 | of the current time.\r |
1204fe83 | 864 | \r |
da1d0201 | 865 | @return The random seed initialized with current time.\r |
866 | \r | |
867 | **/\r | |
868 | UINT32\r | |
7b414b4e | 869 | EFIAPI\r |
da1d0201 | 870 | NetRandomInitSeed (\r |
871 | VOID\r | |
872 | )\r | |
873 | {\r | |
874 | EFI_TIME Time;\r | |
875 | UINT32 Seed;\r | |
876 | \r | |
877 | gRT->GetTime (&Time, NULL);\r | |
36ee91ca | 878 | Seed = (~Time.Hour << 24 | Time.Day << 16 | Time.Minute << 8 | Time.Second);\r |
da1d0201 | 879 | Seed ^= Time.Nanosecond;\r |
880 | Seed ^= Time.Year << 7;\r | |
881 | \r | |
882 | return Seed;\r | |
883 | }\r | |
884 | \r | |
885 | \r | |
886 | /**\r | |
b9008c87 | 887 | Extract a UINT32 from a byte stream.\r |
1204fe83 | 888 | \r |
889 | Copy a UINT32 from a byte stream, then converts it from Network\r | |
b9008c87 | 890 | byte order to host byte order. Use this function to avoid alignment error.\r |
da1d0201 | 891 | \r |
3e7104c2 | 892 | @param[in] Buf The buffer to extract the UINT32.\r |
da1d0201 | 893 | \r |
894 | @return The UINT32 extracted.\r | |
895 | \r | |
896 | **/\r | |
897 | UINT32\r | |
7b414b4e | 898 | EFIAPI\r |
da1d0201 | 899 | NetGetUint32 (\r |
900 | IN UINT8 *Buf\r | |
901 | )\r | |
902 | {\r | |
903 | UINT32 Value;\r | |
904 | \r | |
e48e37fc | 905 | CopyMem (&Value, Buf, sizeof (UINT32));\r |
da1d0201 | 906 | return NTOHL (Value);\r |
907 | }\r | |
908 | \r | |
909 | \r | |
910 | /**\r | |
1204fe83 | 911 | Put a UINT32 to the byte stream in network byte order.\r |
912 | \r | |
913 | Converts a UINT32 from host byte order to network byte order. Then copy it to the\r | |
b9008c87 | 914 | byte stream.\r |
da1d0201 | 915 | \r |
3e7104c2 | 916 | @param[in, out] Buf The buffer to put the UINT32.\r |
3b1464d5 | 917 | @param[in] Data The data to be converted and put into the byte stream.\r |
1204fe83 | 918 | \r |
da1d0201 | 919 | **/\r |
920 | VOID\r | |
7b414b4e | 921 | EFIAPI\r |
da1d0201 | 922 | NetPutUint32 (\r |
3e7104c2 | 923 | IN OUT UINT8 *Buf,\r |
924 | IN UINT32 Data\r | |
da1d0201 | 925 | )\r |
926 | {\r | |
927 | Data = HTONL (Data);\r | |
e48e37fc | 928 | CopyMem (Buf, &Data, sizeof (UINT32));\r |
da1d0201 | 929 | }\r |
930 | \r | |
931 | \r | |
932 | /**\r | |
b9008c87 | 933 | Remove the first node entry on the list, and return the removed node entry.\r |
1204fe83 | 934 | \r |
b9008c87 | 935 | Removes the first node Entry from a doubly linked list. It is up to the caller of\r |
936 | this function to release the memory used by the first node if that is required. On\r | |
1204fe83 | 937 | exit, the removed node is returned.\r |
b9008c87 | 938 | \r |
939 | If Head is NULL, then ASSERT().\r | |
940 | If Head was not initialized, then ASSERT().\r | |
941 | If PcdMaximumLinkedListLength is not zero, and the number of nodes in the\r | |
942 | linked list including the head node is greater than or equal to PcdMaximumLinkedListLength,\r | |
1204fe83 | 943 | then ASSERT().\r |
da1d0201 | 944 | \r |
3e7104c2 | 945 | @param[in, out] Head The list header.\r |
da1d0201 | 946 | \r |
b9008c87 | 947 | @return The first node entry that is removed from the list, NULL if the list is empty.\r |
da1d0201 | 948 | \r |
949 | **/\r | |
e48e37fc | 950 | LIST_ENTRY *\r |
7b414b4e | 951 | EFIAPI\r |
da1d0201 | 952 | NetListRemoveHead (\r |
3e7104c2 | 953 | IN OUT LIST_ENTRY *Head\r |
da1d0201 | 954 | )\r |
955 | {\r | |
e48e37fc | 956 | LIST_ENTRY *First;\r |
da1d0201 | 957 | \r |
958 | ASSERT (Head != NULL);\r | |
959 | \r | |
e48e37fc | 960 | if (IsListEmpty (Head)) {\r |
da1d0201 | 961 | return NULL;\r |
962 | }\r | |
963 | \r | |
964 | First = Head->ForwardLink;\r | |
965 | Head->ForwardLink = First->ForwardLink;\r | |
966 | First->ForwardLink->BackLink = Head;\r | |
967 | \r | |
968 | DEBUG_CODE (\r | |
e48e37fc | 969 | First->ForwardLink = (LIST_ENTRY *) NULL;\r |
970 | First->BackLink = (LIST_ENTRY *) NULL;\r | |
da1d0201 | 971 | );\r |
972 | \r | |
973 | return First;\r | |
974 | }\r | |
975 | \r | |
976 | \r | |
977 | /**\r | |
b9008c87 | 978 | Remove the last node entry on the list and and return the removed node entry.\r |
979 | \r | |
980 | Removes the last node entry from a doubly linked list. It is up to the caller of\r | |
981 | this function to release the memory used by the first node if that is required. On\r | |
1204fe83 | 982 | exit, the removed node is returned.\r |
da1d0201 | 983 | \r |
b9008c87 | 984 | If Head is NULL, then ASSERT().\r |
985 | If Head was not initialized, then ASSERT().\r | |
986 | If PcdMaximumLinkedListLength is not zero, and the number of nodes in the\r | |
987 | linked list including the head node is greater than or equal to PcdMaximumLinkedListLength,\r | |
1204fe83 | 988 | then ASSERT().\r |
989 | \r | |
3e7104c2 | 990 | @param[in, out] Head The list head.\r |
da1d0201 | 991 | \r |
b9008c87 | 992 | @return The last node entry that is removed from the list, NULL if the list is empty.\r |
da1d0201 | 993 | \r |
994 | **/\r | |
e48e37fc | 995 | LIST_ENTRY *\r |
7b414b4e | 996 | EFIAPI\r |
da1d0201 | 997 | NetListRemoveTail (\r |
3e7104c2 | 998 | IN OUT LIST_ENTRY *Head\r |
da1d0201 | 999 | )\r |
1000 | {\r | |
e48e37fc | 1001 | LIST_ENTRY *Last;\r |
da1d0201 | 1002 | \r |
1003 | ASSERT (Head != NULL);\r | |
1004 | \r | |
e48e37fc | 1005 | if (IsListEmpty (Head)) {\r |
da1d0201 | 1006 | return NULL;\r |
1007 | }\r | |
1008 | \r | |
1009 | Last = Head->BackLink;\r | |
1010 | Head->BackLink = Last->BackLink;\r | |
1011 | Last->BackLink->ForwardLink = Head;\r | |
1012 | \r | |
1013 | DEBUG_CODE (\r | |
e48e37fc | 1014 | Last->ForwardLink = (LIST_ENTRY *) NULL;\r |
1015 | Last->BackLink = (LIST_ENTRY *) NULL;\r | |
da1d0201 | 1016 | );\r |
1017 | \r | |
1018 | return Last;\r | |
1019 | }\r | |
1020 | \r | |
1021 | \r | |
1022 | /**\r | |
b9008c87 | 1023 | Insert a new node entry after a designated node entry of a doubly linked list.\r |
1204fe83 | 1024 | \r |
b9008c87 | 1025 | Inserts a new node entry donated by NewEntry after the node entry donated by PrevEntry\r |
1026 | of the doubly linked list.\r | |
1204fe83 | 1027 | \r |
3e7104c2 | 1028 | @param[in, out] PrevEntry The previous entry to insert after.\r |
1029 | @param[in, out] NewEntry The new entry to insert.\r | |
da1d0201 | 1030 | \r |
1031 | **/\r | |
1032 | VOID\r | |
7b414b4e | 1033 | EFIAPI\r |
da1d0201 | 1034 | NetListInsertAfter (\r |
3e7104c2 | 1035 | IN OUT LIST_ENTRY *PrevEntry,\r |
1036 | IN OUT LIST_ENTRY *NewEntry\r | |
da1d0201 | 1037 | )\r |
1038 | {\r | |
1039 | NewEntry->BackLink = PrevEntry;\r | |
1040 | NewEntry->ForwardLink = PrevEntry->ForwardLink;\r | |
1041 | PrevEntry->ForwardLink->BackLink = NewEntry;\r | |
1042 | PrevEntry->ForwardLink = NewEntry;\r | |
1043 | }\r | |
1044 | \r | |
1045 | \r | |
1046 | /**\r | |
b9008c87 | 1047 | Insert a new node entry before a designated node entry of a doubly linked list.\r |
1204fe83 | 1048 | \r |
b9008c87 | 1049 | Inserts a new node entry donated by NewEntry after the node entry donated by PostEntry\r |
1050 | of the doubly linked list.\r | |
1204fe83 | 1051 | \r |
3e7104c2 | 1052 | @param[in, out] PostEntry The entry to insert before.\r |
1053 | @param[in, out] NewEntry The new entry to insert.\r | |
da1d0201 | 1054 | \r |
1055 | **/\r | |
1056 | VOID\r | |
7b414b4e | 1057 | EFIAPI\r |
da1d0201 | 1058 | NetListInsertBefore (\r |
3e7104c2 | 1059 | IN OUT LIST_ENTRY *PostEntry,\r |
1060 | IN OUT LIST_ENTRY *NewEntry\r | |
da1d0201 | 1061 | )\r |
1062 | {\r | |
1063 | NewEntry->ForwardLink = PostEntry;\r | |
1064 | NewEntry->BackLink = PostEntry->BackLink;\r | |
1065 | PostEntry->BackLink->ForwardLink = NewEntry;\r | |
1066 | PostEntry->BackLink = NewEntry;\r | |
1067 | }\r | |
1068 | \r | |
216f7970 | 1069 | /**\r |
1070 | Safe destroy nodes in a linked list, and return the length of the list after all possible operations finished.\r | |
1071 | \r | |
1072 | Destroy network child instance list by list traversals is not safe due to graph dependencies between nodes.\r | |
1073 | This function performs a safe traversal to destroy these nodes by checking to see if the node being destroyed\r | |
1074 | has been removed from the list or not.\r | |
1075 | If it has been removed, then restart the traversal from the head.\r | |
1076 | If it hasn't been removed, then continue with the next node directly.\r | |
1077 | This function will end the iterate and return the CallBack's last return value if error happens,\r | |
1078 | or retrun EFI_SUCCESS if 2 complete passes are made with no changes in the number of children in the list. \r | |
1079 | \r | |
1080 | @param[in] List The head of the list.\r | |
1081 | @param[in] CallBack Pointer to the callback function to destroy one node in the list.\r | |
1082 | @param[in] Context Pointer to the callback function's context: corresponds to the\r | |
1083 | parameter Context in NET_DESTROY_LINK_LIST_CALLBACK.\r | |
1084 | @param[out] ListLength The length of the link list if the function returns successfully.\r | |
1085 | \r | |
1086 | @retval EFI_SUCCESS Two complete passes are made with no changes in the number of children.\r | |
1087 | @retval EFI_INVALID_PARAMETER The input parameter is invalid.\r | |
1088 | @retval Others Return the CallBack's last return value.\r | |
1089 | \r | |
1090 | **/\r | |
1091 | EFI_STATUS\r | |
1092 | EFIAPI\r | |
1093 | NetDestroyLinkList (\r | |
1094 | IN LIST_ENTRY *List,\r | |
1095 | IN NET_DESTROY_LINK_LIST_CALLBACK CallBack,\r | |
1096 | IN VOID *Context, OPTIONAL\r | |
1097 | OUT UINTN *ListLength OPTIONAL\r | |
1f7eb561 | 1098 | )\r |
216f7970 | 1099 | {\r |
1100 | UINTN PreviousLength;\r | |
1101 | LIST_ENTRY *Entry;\r | |
1102 | LIST_ENTRY *Ptr;\r | |
1103 | UINTN Length;\r | |
1104 | EFI_STATUS Status;\r | |
1105 | \r | |
1106 | if (List == NULL || CallBack == NULL) {\r | |
1107 | return EFI_INVALID_PARAMETER;\r | |
1108 | }\r | |
1109 | \r | |
1110 | Length = 0;\r | |
1111 | do {\r | |
1112 | PreviousLength = Length;\r | |
1113 | Entry = GetFirstNode (List);\r | |
1114 | while (!IsNull (List, Entry)) {\r | |
1115 | Status = CallBack (Entry, Context);\r | |
1116 | if (EFI_ERROR (Status)) {\r | |
1117 | return Status;\r | |
1118 | }\r | |
1119 | //\r | |
1120 | // Walk through the list to see whether the Entry has been removed or not.\r | |
1121 | // If the Entry still exists, just try to destroy the next one.\r | |
1122 | // If not, go back to the start point to iterate the list again.\r | |
1123 | //\r | |
1124 | for (Ptr = List->ForwardLink; Ptr != List; Ptr = Ptr->ForwardLink) {\r | |
1125 | if (Ptr == Entry) {\r | |
1126 | break;\r | |
1127 | }\r | |
1128 | }\r | |
1129 | if (Ptr == Entry) {\r | |
1130 | Entry = GetNextNode (List, Entry);\r | |
1131 | } else {\r | |
1132 | Entry = GetFirstNode (List);\r | |
1133 | }\r | |
1134 | }\r | |
1135 | for (Length = 0, Ptr = List->ForwardLink; Ptr != List; Length++, Ptr = Ptr->ForwardLink);\r | |
1136 | } while (Length != PreviousLength);\r | |
1137 | \r | |
1138 | if (ListLength != NULL) {\r | |
1139 | *ListLength = Length;\r | |
1140 | }\r | |
1141 | return EFI_SUCCESS;\r | |
1142 | }\r | |
1143 | \r | |
1144 | /**\r | |
1145 | This function checks the input Handle to see if it's one of these handles in ChildHandleBuffer.\r | |
1146 | \r | |
1147 | @param[in] Handle Handle to be checked.\r | |
1148 | @param[in] NumberOfChildren Number of Handles in ChildHandleBuffer.\r | |
1149 | @param[in] ChildHandleBuffer An array of child handles to be freed. May be NULL\r | |
1150 | if NumberOfChildren is 0.\r | |
1151 | \r | |
1152 | @retval TURE Found the input Handle in ChildHandleBuffer.\r | |
1153 | @retval FALSE Can't find the input Handle in ChildHandleBuffer.\r | |
1154 | \r | |
1155 | **/\r | |
1156 | BOOLEAN\r | |
f8c075d1 | 1157 | EFIAPI\r |
216f7970 | 1158 | NetIsInHandleBuffer (\r |
1159 | IN EFI_HANDLE Handle,\r | |
1160 | IN UINTN NumberOfChildren,\r | |
1161 | IN EFI_HANDLE *ChildHandleBuffer OPTIONAL\r | |
1f7eb561 | 1162 | )\r |
216f7970 | 1163 | {\r |
1164 | UINTN Index;\r | |
1165 | \r | |
1166 | if (NumberOfChildren == 0 || ChildHandleBuffer == NULL) {\r | |
1167 | return FALSE;\r | |
1168 | }\r | |
1169 | \r | |
1170 | for (Index = 0; Index < NumberOfChildren; Index++) {\r | |
1171 | if (Handle == ChildHandleBuffer[Index]) {\r | |
1172 | return TRUE;\r | |
1173 | }\r | |
1174 | }\r | |
1175 | \r | |
1176 | return FALSE;\r | |
1177 | }\r | |
1178 | \r | |
da1d0201 | 1179 | \r |
1180 | /**\r | |
1181 | Initialize the netmap. Netmap is a reposity to keep the <Key, Value> pairs.\r | |
1204fe83 | 1182 | \r |
1183 | Initialize the forward and backward links of two head nodes donated by Map->Used\r | |
b9008c87 | 1184 | and Map->Recycled of two doubly linked lists.\r |
1185 | Initializes the count of the <Key, Value> pairs in the netmap to zero.\r | |
1204fe83 | 1186 | \r |
b9008c87 | 1187 | If Map is NULL, then ASSERT().\r |
8f5e6151 | 1188 | If the address of Map->Used is NULL, then ASSERT().\r |
b9008c87 | 1189 | If the address of Map->Recycled is NULl, then ASSERT().\r |
1204fe83 | 1190 | \r |
3e7104c2 | 1191 | @param[in, out] Map The netmap to initialize.\r |
da1d0201 | 1192 | \r |
1193 | **/\r | |
1194 | VOID\r | |
7b414b4e | 1195 | EFIAPI\r |
da1d0201 | 1196 | NetMapInit (\r |
3e7104c2 | 1197 | IN OUT NET_MAP *Map\r |
da1d0201 | 1198 | )\r |
1199 | {\r | |
1200 | ASSERT (Map != NULL);\r | |
1201 | \r | |
e48e37fc | 1202 | InitializeListHead (&Map->Used);\r |
1203 | InitializeListHead (&Map->Recycled);\r | |
da1d0201 | 1204 | Map->Count = 0;\r |
1205 | }\r | |
1206 | \r | |
1207 | \r | |
1208 | /**\r | |
1209 | To clean up the netmap, that is, release allocated memories.\r | |
1204fe83 | 1210 | \r |
b9008c87 | 1211 | Removes all nodes of the Used doubly linked list and free memory of all related netmap items.\r |
1212 | Removes all nodes of the Recycled doubly linked list and free memory of all related netmap items.\r | |
1213 | The number of the <Key, Value> pairs in the netmap is set to be zero.\r | |
1204fe83 | 1214 | \r |
b9008c87 | 1215 | If Map is NULL, then ASSERT().\r |
1204fe83 | 1216 | \r |
3e7104c2 | 1217 | @param[in, out] Map The netmap to clean up.\r |
da1d0201 | 1218 | \r |
1219 | **/\r | |
1220 | VOID\r | |
7b414b4e | 1221 | EFIAPI\r |
da1d0201 | 1222 | NetMapClean (\r |
3e7104c2 | 1223 | IN OUT NET_MAP *Map\r |
da1d0201 | 1224 | )\r |
1225 | {\r | |
1226 | NET_MAP_ITEM *Item;\r | |
e48e37fc | 1227 | LIST_ENTRY *Entry;\r |
1228 | LIST_ENTRY *Next;\r | |
da1d0201 | 1229 | \r |
1230 | ASSERT (Map != NULL);\r | |
1231 | \r | |
1232 | NET_LIST_FOR_EACH_SAFE (Entry, Next, &Map->Used) {\r | |
1233 | Item = NET_LIST_USER_STRUCT (Entry, NET_MAP_ITEM, Link);\r | |
1234 | \r | |
e48e37fc | 1235 | RemoveEntryList (&Item->Link);\r |
da1d0201 | 1236 | Map->Count--;\r |
1237 | \r | |
e48e37fc | 1238 | gBS->FreePool (Item);\r |
da1d0201 | 1239 | }\r |
1240 | \r | |
e48e37fc | 1241 | ASSERT ((Map->Count == 0) && IsListEmpty (&Map->Used));\r |
da1d0201 | 1242 | \r |
1243 | NET_LIST_FOR_EACH_SAFE (Entry, Next, &Map->Recycled) {\r | |
1244 | Item = NET_LIST_USER_STRUCT (Entry, NET_MAP_ITEM, Link);\r | |
1245 | \r | |
e48e37fc | 1246 | RemoveEntryList (&Item->Link);\r |
1247 | gBS->FreePool (Item);\r | |
da1d0201 | 1248 | }\r |
1249 | \r | |
e48e37fc | 1250 | ASSERT (IsListEmpty (&Map->Recycled));\r |
da1d0201 | 1251 | }\r |
1252 | \r | |
1253 | \r | |
1254 | /**\r | |
b9008c87 | 1255 | Test whether the netmap is empty and return true if it is.\r |
1204fe83 | 1256 | \r |
b9008c87 | 1257 | If the number of the <Key, Value> pairs in the netmap is zero, return TRUE.\r |
1204fe83 | 1258 | \r |
b9008c87 | 1259 | If Map is NULL, then ASSERT().\r |
1204fe83 | 1260 | \r |
1261 | \r | |
3e7104c2 | 1262 | @param[in] Map The net map to test.\r |
da1d0201 | 1263 | \r |
1264 | @return TRUE if the netmap is empty, otherwise FALSE.\r | |
1265 | \r | |
1266 | **/\r | |
1267 | BOOLEAN\r | |
7b414b4e | 1268 | EFIAPI\r |
da1d0201 | 1269 | NetMapIsEmpty (\r |
1270 | IN NET_MAP *Map\r | |
1271 | )\r | |
1272 | {\r | |
1273 | ASSERT (Map != NULL);\r | |
1274 | return (BOOLEAN) (Map->Count == 0);\r | |
1275 | }\r | |
1276 | \r | |
1277 | \r | |
1278 | /**\r | |
1279 | Return the number of the <Key, Value> pairs in the netmap.\r | |
1280 | \r | |
3e7104c2 | 1281 | @param[in] Map The netmap to get the entry number.\r |
da1d0201 | 1282 | \r |
1283 | @return The entry number in the netmap.\r | |
1284 | \r | |
1285 | **/\r | |
1286 | UINTN\r | |
7b414b4e | 1287 | EFIAPI\r |
da1d0201 | 1288 | NetMapGetCount (\r |
1289 | IN NET_MAP *Map\r | |
1290 | )\r | |
1291 | {\r | |
1292 | return Map->Count;\r | |
1293 | }\r | |
1294 | \r | |
1295 | \r | |
1296 | /**\r | |
1204fe83 | 1297 | Return one allocated item.\r |
1298 | \r | |
1299 | If the Recycled doubly linked list of the netmap is empty, it will try to allocate\r | |
b9008c87 | 1300 | a batch of items if there are enough resources and add corresponding nodes to the begining\r |
1301 | of the Recycled doubly linked list of the netmap. Otherwise, it will directly remove\r | |
1302 | the fist node entry of the Recycled doubly linked list and return the corresponding item.\r | |
1204fe83 | 1303 | \r |
b9008c87 | 1304 | If Map is NULL, then ASSERT().\r |
1204fe83 | 1305 | \r |
3e7104c2 | 1306 | @param[in, out] Map The netmap to allocate item for.\r |
da1d0201 | 1307 | \r |
3e7104c2 | 1308 | @return The allocated item. If NULL, the\r |
1309 | allocation failed due to resource limit.\r | |
da1d0201 | 1310 | \r |
1311 | **/\r | |
da1d0201 | 1312 | NET_MAP_ITEM *\r |
1313 | NetMapAllocItem (\r | |
3e7104c2 | 1314 | IN OUT NET_MAP *Map\r |
da1d0201 | 1315 | )\r |
1316 | {\r | |
1317 | NET_MAP_ITEM *Item;\r | |
e48e37fc | 1318 | LIST_ENTRY *Head;\r |
da1d0201 | 1319 | UINTN Index;\r |
1320 | \r | |
1321 | ASSERT (Map != NULL);\r | |
1322 | \r | |
1323 | Head = &Map->Recycled;\r | |
1324 | \r | |
e48e37fc | 1325 | if (IsListEmpty (Head)) {\r |
da1d0201 | 1326 | for (Index = 0; Index < NET_MAP_INCREAMENT; Index++) {\r |
e48e37fc | 1327 | Item = AllocatePool (sizeof (NET_MAP_ITEM));\r |
da1d0201 | 1328 | \r |
1329 | if (Item == NULL) {\r | |
1330 | if (Index == 0) {\r | |
1331 | return NULL;\r | |
1332 | }\r | |
1333 | \r | |
1334 | break;\r | |
1335 | }\r | |
1336 | \r | |
e48e37fc | 1337 | InsertHeadList (Head, &Item->Link);\r |
da1d0201 | 1338 | }\r |
1339 | }\r | |
1340 | \r | |
1341 | Item = NET_LIST_HEAD (Head, NET_MAP_ITEM, Link);\r | |
1342 | NetListRemoveHead (Head);\r | |
1343 | \r | |
1344 | return Item;\r | |
1345 | }\r | |
1346 | \r | |
1347 | \r | |
1348 | /**\r | |
1349 | Allocate an item to save the <Key, Value> pair to the head of the netmap.\r | |
1204fe83 | 1350 | \r |
b9008c87 | 1351 | Allocate an item to save the <Key, Value> pair and add corresponding node entry\r |
1204fe83 | 1352 | to the beginning of the Used doubly linked list. The number of the <Key, Value>\r |
b9008c87 | 1353 | pairs in the netmap increase by 1.\r |
da1d0201 | 1354 | \r |
b9008c87 | 1355 | If Map is NULL, then ASSERT().\r |
1204fe83 | 1356 | \r |
3e7104c2 | 1357 | @param[in, out] Map The netmap to insert into.\r |
1358 | @param[in] Key The user's key.\r | |
1359 | @param[in] Value The user's value for the key.\r | |
da1d0201 | 1360 | \r |
3e7104c2 | 1361 | @retval EFI_OUT_OF_RESOURCES Failed to allocate the memory for the item.\r |
1362 | @retval EFI_SUCCESS The item is inserted to the head.\r | |
da1d0201 | 1363 | \r |
1364 | **/\r | |
1365 | EFI_STATUS\r | |
7b414b4e | 1366 | EFIAPI\r |
da1d0201 | 1367 | NetMapInsertHead (\r |
3e7104c2 | 1368 | IN OUT NET_MAP *Map,\r |
da1d0201 | 1369 | IN VOID *Key,\r |
1370 | IN VOID *Value OPTIONAL\r | |
1371 | )\r | |
1372 | {\r | |
1373 | NET_MAP_ITEM *Item;\r | |
1374 | \r | |
1375 | ASSERT (Map != NULL);\r | |
1376 | \r | |
1377 | Item = NetMapAllocItem (Map);\r | |
1378 | \r | |
1379 | if (Item == NULL) {\r | |
1380 | return EFI_OUT_OF_RESOURCES;\r | |
1381 | }\r | |
1382 | \r | |
1383 | Item->Key = Key;\r | |
1384 | Item->Value = Value;\r | |
e48e37fc | 1385 | InsertHeadList (&Map->Used, &Item->Link);\r |
da1d0201 | 1386 | \r |
1387 | Map->Count++;\r | |
1388 | return EFI_SUCCESS;\r | |
1389 | }\r | |
1390 | \r | |
1391 | \r | |
1392 | /**\r | |
1393 | Allocate an item to save the <Key, Value> pair to the tail of the netmap.\r | |
1394 | \r | |
b9008c87 | 1395 | Allocate an item to save the <Key, Value> pair and add corresponding node entry\r |
1204fe83 | 1396 | to the tail of the Used doubly linked list. The number of the <Key, Value>\r |
b9008c87 | 1397 | pairs in the netmap increase by 1.\r |
1398 | \r | |
1399 | If Map is NULL, then ASSERT().\r | |
1204fe83 | 1400 | \r |
3e7104c2 | 1401 | @param[in, out] Map The netmap to insert into.\r |
1402 | @param[in] Key The user's key.\r | |
1403 | @param[in] Value The user's value for the key.\r | |
da1d0201 | 1404 | \r |
3e7104c2 | 1405 | @retval EFI_OUT_OF_RESOURCES Failed to allocate the memory for the item.\r |
1406 | @retval EFI_SUCCESS The item is inserted to the tail.\r | |
da1d0201 | 1407 | \r |
1408 | **/\r | |
1409 | EFI_STATUS\r | |
7b414b4e | 1410 | EFIAPI\r |
da1d0201 | 1411 | NetMapInsertTail (\r |
3e7104c2 | 1412 | IN OUT NET_MAP *Map,\r |
da1d0201 | 1413 | IN VOID *Key,\r |
1414 | IN VOID *Value OPTIONAL\r | |
1415 | )\r | |
1416 | {\r | |
1417 | NET_MAP_ITEM *Item;\r | |
1418 | \r | |
1419 | ASSERT (Map != NULL);\r | |
1420 | \r | |
1421 | Item = NetMapAllocItem (Map);\r | |
1422 | \r | |
1423 | if (Item == NULL) {\r | |
1424 | return EFI_OUT_OF_RESOURCES;\r | |
1425 | }\r | |
1426 | \r | |
1427 | Item->Key = Key;\r | |
1428 | Item->Value = Value;\r | |
e48e37fc | 1429 | InsertTailList (&Map->Used, &Item->Link);\r |
da1d0201 | 1430 | \r |
1431 | Map->Count++;\r | |
1432 | \r | |
1433 | return EFI_SUCCESS;\r | |
1434 | }\r | |
1435 | \r | |
1436 | \r | |
1437 | /**\r | |
b9008c87 | 1438 | Check whether the item is in the Map and return TRUE if it is.\r |
da1d0201 | 1439 | \r |
3e7104c2 | 1440 | @param[in] Map The netmap to search within.\r |
1441 | @param[in] Item The item to search.\r | |
da1d0201 | 1442 | \r |
1443 | @return TRUE if the item is in the netmap, otherwise FALSE.\r | |
1444 | \r | |
1445 | **/\r | |
da1d0201 | 1446 | BOOLEAN\r |
1447 | NetItemInMap (\r | |
1448 | IN NET_MAP *Map,\r | |
1449 | IN NET_MAP_ITEM *Item\r | |
1450 | )\r | |
1451 | {\r | |
e48e37fc | 1452 | LIST_ENTRY *ListEntry;\r |
da1d0201 | 1453 | \r |
1454 | NET_LIST_FOR_EACH (ListEntry, &Map->Used) {\r | |
1455 | if (ListEntry == &Item->Link) {\r | |
1456 | return TRUE;\r | |
1457 | }\r | |
1458 | }\r | |
1459 | \r | |
1460 | return FALSE;\r | |
1461 | }\r | |
1462 | \r | |
1463 | \r | |
1464 | /**\r | |
b9008c87 | 1465 | Find the key in the netmap and returns the point to the item contains the Key.\r |
1204fe83 | 1466 | \r |
1467 | Iterate the Used doubly linked list of the netmap to get every item. Compare the key of every\r | |
b9008c87 | 1468 | item with the key to search. It returns the point to the item contains the Key if found.\r |
da1d0201 | 1469 | \r |
b9008c87 | 1470 | If Map is NULL, then ASSERT().\r |
1204fe83 | 1471 | \r |
3e7104c2 | 1472 | @param[in] Map The netmap to search within.\r |
1473 | @param[in] Key The key to search.\r | |
da1d0201 | 1474 | \r |
1475 | @return The point to the item contains the Key, or NULL if Key isn't in the map.\r | |
1476 | \r | |
1477 | **/\r | |
1478 | NET_MAP_ITEM *\r | |
7b414b4e | 1479 | EFIAPI\r |
da1d0201 | 1480 | NetMapFindKey (\r |
1481 | IN NET_MAP *Map,\r | |
1482 | IN VOID *Key\r | |
1483 | )\r | |
1484 | {\r | |
e48e37fc | 1485 | LIST_ENTRY *Entry;\r |
da1d0201 | 1486 | NET_MAP_ITEM *Item;\r |
1487 | \r | |
1488 | ASSERT (Map != NULL);\r | |
1489 | \r | |
1490 | NET_LIST_FOR_EACH (Entry, &Map->Used) {\r | |
1491 | Item = NET_LIST_USER_STRUCT (Entry, NET_MAP_ITEM, Link);\r | |
1492 | \r | |
1493 | if (Item->Key == Key) {\r | |
1494 | return Item;\r | |
1495 | }\r | |
1496 | }\r | |
1497 | \r | |
1498 | return NULL;\r | |
1499 | }\r | |
1500 | \r | |
1501 | \r | |
1502 | /**\r | |
b9008c87 | 1503 | Remove the node entry of the item from the netmap and return the key of the removed item.\r |
1204fe83 | 1504 | \r |
1505 | Remove the node entry of the item from the Used doubly linked list of the netmap.\r | |
1506 | The number of the <Key, Value> pairs in the netmap decrease by 1. Then add the node\r | |
b9008c87 | 1507 | entry of the item to the Recycled doubly linked list of the netmap. If Value is not NULL,\r |
1508 | Value will point to the value of the item. It returns the key of the removed item.\r | |
1204fe83 | 1509 | \r |
b9008c87 | 1510 | If Map is NULL, then ASSERT().\r |
1511 | If Item is NULL, then ASSERT().\r | |
1512 | if item in not in the netmap, then ASSERT().\r | |
1204fe83 | 1513 | \r |
3e7104c2 | 1514 | @param[in, out] Map The netmap to remove the item from.\r |
1515 | @param[in, out] Item The item to remove.\r | |
1516 | @param[out] Value The variable to receive the value if not NULL.\r | |
da1d0201 | 1517 | \r |
3e7104c2 | 1518 | @return The key of the removed item.\r |
da1d0201 | 1519 | \r |
1520 | **/\r | |
1521 | VOID *\r | |
7b414b4e | 1522 | EFIAPI\r |
da1d0201 | 1523 | NetMapRemoveItem (\r |
3e7104c2 | 1524 | IN OUT NET_MAP *Map,\r |
1525 | IN OUT NET_MAP_ITEM *Item,\r | |
1526 | OUT VOID **Value OPTIONAL\r | |
da1d0201 | 1527 | )\r |
1528 | {\r | |
1529 | ASSERT ((Map != NULL) && (Item != NULL));\r | |
1530 | ASSERT (NetItemInMap (Map, Item));\r | |
1531 | \r | |
e48e37fc | 1532 | RemoveEntryList (&Item->Link);\r |
da1d0201 | 1533 | Map->Count--;\r |
e48e37fc | 1534 | InsertHeadList (&Map->Recycled, &Item->Link);\r |
da1d0201 | 1535 | \r |
1536 | if (Value != NULL) {\r | |
1537 | *Value = Item->Value;\r | |
1538 | }\r | |
1539 | \r | |
1540 | return Item->Key;\r | |
1541 | }\r | |
1542 | \r | |
1543 | \r | |
1544 | /**\r | |
b9008c87 | 1545 | Remove the first node entry on the netmap and return the key of the removed item.\r |
da1d0201 | 1546 | \r |
1204fe83 | 1547 | Remove the first node entry from the Used doubly linked list of the netmap.\r |
1548 | The number of the <Key, Value> pairs in the netmap decrease by 1. Then add the node\r | |
b9008c87 | 1549 | entry to the Recycled doubly linked list of the netmap. If parameter Value is not NULL,\r |
1550 | parameter Value will point to the value of the item. It returns the key of the removed item.\r | |
1204fe83 | 1551 | \r |
b9008c87 | 1552 | If Map is NULL, then ASSERT().\r |
1553 | If the Used doubly linked list is empty, then ASSERT().\r | |
1204fe83 | 1554 | \r |
3e7104c2 | 1555 | @param[in, out] Map The netmap to remove the head from.\r |
1556 | @param[out] Value The variable to receive the value if not NULL.\r | |
da1d0201 | 1557 | \r |
3e7104c2 | 1558 | @return The key of the item removed.\r |
da1d0201 | 1559 | \r |
1560 | **/\r | |
1561 | VOID *\r | |
7b414b4e | 1562 | EFIAPI\r |
da1d0201 | 1563 | NetMapRemoveHead (\r |
3e7104c2 | 1564 | IN OUT NET_MAP *Map,\r |
da1d0201 | 1565 | OUT VOID **Value OPTIONAL\r |
1566 | )\r | |
1567 | {\r | |
1568 | NET_MAP_ITEM *Item;\r | |
1569 | \r | |
1570 | //\r | |
1571 | // Often, it indicates a programming error to remove\r | |
1572 | // the first entry in an empty list\r | |
1573 | //\r | |
e48e37fc | 1574 | ASSERT (Map && !IsListEmpty (&Map->Used));\r |
da1d0201 | 1575 | \r |
1576 | Item = NET_LIST_HEAD (&Map->Used, NET_MAP_ITEM, Link);\r | |
e48e37fc | 1577 | RemoveEntryList (&Item->Link);\r |
da1d0201 | 1578 | Map->Count--;\r |
e48e37fc | 1579 | InsertHeadList (&Map->Recycled, &Item->Link);\r |
da1d0201 | 1580 | \r |
1581 | if (Value != NULL) {\r | |
1582 | *Value = Item->Value;\r | |
1583 | }\r | |
1584 | \r | |
1585 | return Item->Key;\r | |
1586 | }\r | |
1587 | \r | |
1588 | \r | |
1589 | /**\r | |
b9008c87 | 1590 | Remove the last node entry on the netmap and return the key of the removed item.\r |
da1d0201 | 1591 | \r |
1204fe83 | 1592 | Remove the last node entry from the Used doubly linked list of the netmap.\r |
1593 | The number of the <Key, Value> pairs in the netmap decrease by 1. Then add the node\r | |
b9008c87 | 1594 | entry to the Recycled doubly linked list of the netmap. If parameter Value is not NULL,\r |
1595 | parameter Value will point to the value of the item. It returns the key of the removed item.\r | |
1204fe83 | 1596 | \r |
b9008c87 | 1597 | If Map is NULL, then ASSERT().\r |
1598 | If the Used doubly linked list is empty, then ASSERT().\r | |
1204fe83 | 1599 | \r |
3e7104c2 | 1600 | @param[in, out] Map The netmap to remove the tail from.\r |
1601 | @param[out] Value The variable to receive the value if not NULL.\r | |
da1d0201 | 1602 | \r |
3e7104c2 | 1603 | @return The key of the item removed.\r |
da1d0201 | 1604 | \r |
1605 | **/\r | |
1606 | VOID *\r | |
7b414b4e | 1607 | EFIAPI\r |
da1d0201 | 1608 | NetMapRemoveTail (\r |
3e7104c2 | 1609 | IN OUT NET_MAP *Map,\r |
da1d0201 | 1610 | OUT VOID **Value OPTIONAL\r |
1611 | )\r | |
1612 | {\r | |
1613 | NET_MAP_ITEM *Item;\r | |
1614 | \r | |
1615 | //\r | |
1616 | // Often, it indicates a programming error to remove\r | |
1617 | // the last entry in an empty list\r | |
1618 | //\r | |
e48e37fc | 1619 | ASSERT (Map && !IsListEmpty (&Map->Used));\r |
da1d0201 | 1620 | \r |
1621 | Item = NET_LIST_TAIL (&Map->Used, NET_MAP_ITEM, Link);\r | |
e48e37fc | 1622 | RemoveEntryList (&Item->Link);\r |
da1d0201 | 1623 | Map->Count--;\r |
e48e37fc | 1624 | InsertHeadList (&Map->Recycled, &Item->Link);\r |
da1d0201 | 1625 | \r |
1626 | if (Value != NULL) {\r | |
1627 | *Value = Item->Value;\r | |
1628 | }\r | |
1629 | \r | |
1630 | return Item->Key;\r | |
1631 | }\r | |
1632 | \r | |
1633 | \r | |
1634 | /**\r | |
b9008c87 | 1635 | Iterate through the netmap and call CallBack for each item.\r |
1204fe83 | 1636 | \r |
b9008c87 | 1637 | It will contiue the traverse if CallBack returns EFI_SUCCESS, otherwise, break\r |
1204fe83 | 1638 | from the loop. It returns the CallBack's last return value. This function is\r |
b9008c87 | 1639 | delete safe for the current item.\r |
da1d0201 | 1640 | \r |
b9008c87 | 1641 | If Map is NULL, then ASSERT().\r |
1642 | If CallBack is NULL, then ASSERT().\r | |
1204fe83 | 1643 | \r |
3e7104c2 | 1644 | @param[in] Map The Map to iterate through.\r |
1645 | @param[in] CallBack The callback function to call for each item.\r | |
1646 | @param[in] Arg The opaque parameter to the callback.\r | |
da1d0201 | 1647 | \r |
3e7104c2 | 1648 | @retval EFI_SUCCESS There is no item in the netmap or CallBack for each item\r |
1649 | return EFI_SUCCESS.\r | |
1650 | @retval Others It returns the CallBack's last return value.\r | |
da1d0201 | 1651 | \r |
1652 | **/\r | |
1653 | EFI_STATUS\r | |
7b414b4e | 1654 | EFIAPI\r |
da1d0201 | 1655 | NetMapIterate (\r |
1656 | IN NET_MAP *Map,\r | |
1657 | IN NET_MAP_CALLBACK CallBack,\r | |
e2851998 | 1658 | IN VOID *Arg OPTIONAL\r |
da1d0201 | 1659 | )\r |
1660 | {\r | |
1661 | \r | |
e48e37fc | 1662 | LIST_ENTRY *Entry;\r |
1663 | LIST_ENTRY *Next;\r | |
1664 | LIST_ENTRY *Head;\r | |
b9008c87 | 1665 | NET_MAP_ITEM *Item;\r |
1666 | EFI_STATUS Result;\r | |
da1d0201 | 1667 | \r |
1668 | ASSERT ((Map != NULL) && (CallBack != NULL));\r | |
1669 | \r | |
1670 | Head = &Map->Used;\r | |
1671 | \r | |
e48e37fc | 1672 | if (IsListEmpty (Head)) {\r |
da1d0201 | 1673 | return EFI_SUCCESS;\r |
1674 | }\r | |
1675 | \r | |
1676 | NET_LIST_FOR_EACH_SAFE (Entry, Next, Head) {\r | |
1677 | Item = NET_LIST_USER_STRUCT (Entry, NET_MAP_ITEM, Link);\r | |
1678 | Result = CallBack (Map, Item, Arg);\r | |
1679 | \r | |
1680 | if (EFI_ERROR (Result)) {\r | |
1681 | return Result;\r | |
1682 | }\r | |
1683 | }\r | |
1684 | \r | |
1685 | return EFI_SUCCESS;\r | |
1686 | }\r | |
1687 | \r | |
1688 | \r | |
1dc1b43f | 1689 | /**\r |
1690 | Internal function to get the child handle of the NIC handle.\r | |
1691 | \r | |
1692 | @param[in] Controller NIC controller handle.\r | |
1693 | @param[out] ChildHandle Returned child handle.\r | |
1694 | \r | |
1695 | @retval EFI_SUCCESS Successfully to get child handle.\r | |
1696 | @retval Others Failed to get child handle.\r | |
1697 | \r | |
1698 | **/\r | |
1699 | EFI_STATUS\r | |
1700 | NetGetChildHandle (\r | |
1701 | IN EFI_HANDLE Controller,\r | |
1702 | OUT EFI_HANDLE *ChildHandle\r | |
1703 | )\r | |
1704 | {\r | |
1705 | EFI_STATUS Status;\r | |
1706 | EFI_HANDLE *Handles;\r | |
1707 | UINTN HandleCount;\r | |
1708 | UINTN Index;\r | |
1709 | EFI_DEVICE_PATH_PROTOCOL *ChildDeviceDevicePath;\r | |
1710 | VENDOR_DEVICE_PATH *VendorDeviceNode;\r | |
1711 | \r | |
1712 | //\r | |
1713 | // Locate all EFI Hii Config Access protocols\r | |
1714 | //\r | |
1715 | Status = gBS->LocateHandleBuffer (\r | |
1716 | ByProtocol,\r | |
1717 | &gEfiHiiConfigAccessProtocolGuid,\r | |
1718 | NULL,\r | |
1719 | &HandleCount,\r | |
1720 | &Handles\r | |
1721 | );\r | |
1722 | if (EFI_ERROR (Status) || (HandleCount == 0)) {\r | |
1723 | return Status;\r | |
1724 | }\r | |
1725 | \r | |
1726 | Status = EFI_NOT_FOUND;\r | |
1727 | \r | |
1728 | for (Index = 0; Index < HandleCount; Index++) {\r | |
1729 | \r | |
1730 | Status = EfiTestChildHandle (Controller, Handles[Index], &gEfiManagedNetworkServiceBindingProtocolGuid);\r | |
1731 | if (!EFI_ERROR (Status)) {\r | |
1732 | //\r | |
1733 | // Get device path on the child handle\r | |
1734 | //\r | |
1735 | Status = gBS->HandleProtocol (\r | |
1736 | Handles[Index],\r | |
1737 | &gEfiDevicePathProtocolGuid,\r | |
1738 | (VOID **) &ChildDeviceDevicePath\r | |
1739 | );\r | |
1740 | \r | |
1741 | if (!EFI_ERROR (Status)) {\r | |
1742 | while (!IsDevicePathEnd (ChildDeviceDevicePath)) {\r | |
1743 | ChildDeviceDevicePath = NextDevicePathNode (ChildDeviceDevicePath);\r | |
1744 | //\r | |
1745 | // Parse one instance\r | |
1746 | //\r | |
1747 | if (ChildDeviceDevicePath->Type == HARDWARE_DEVICE_PATH &&\r | |
1748 | ChildDeviceDevicePath->SubType == HW_VENDOR_DP) {\r | |
1749 | VendorDeviceNode = (VENDOR_DEVICE_PATH *) ChildDeviceDevicePath;\r | |
1750 | if (CompareMem (&VendorDeviceNode->Guid, &gEfiNicIp4ConfigVariableGuid, sizeof (EFI_GUID)) == 0) {\r | |
1751 | //\r | |
1752 | // Found item matched gEfiNicIp4ConfigVariableGuid\r | |
1753 | //\r | |
1754 | *ChildHandle = Handles[Index];\r | |
ad108abe | 1755 | FreePool (Handles);\r |
1dc1b43f | 1756 | return EFI_SUCCESS;\r |
1757 | }\r | |
1758 | }\r | |
1759 | }\r | |
1760 | }\r | |
1761 | }\r | |
1762 | }\r | |
1763 | \r | |
ad108abe | 1764 | FreePool (Handles);\r |
1dc1b43f | 1765 | return Status;\r |
1766 | }\r | |
1767 | \r | |
1768 | \r | |
da1d0201 | 1769 | /**\r |
1770 | This is the default unload handle for all the network drivers.\r | |
1771 | \r | |
b9008c87 | 1772 | Disconnect the driver specified by ImageHandle from all the devices in the handle database.\r |
1773 | Uninstall all the protocols installed in the driver entry point.\r | |
1204fe83 | 1774 | \r |
3e7104c2 | 1775 | @param[in] ImageHandle The drivers' driver image.\r |
da1d0201 | 1776 | \r |
1777 | @retval EFI_SUCCESS The image is unloaded.\r | |
1778 | @retval Others Failed to unload the image.\r | |
1779 | \r | |
1780 | **/\r | |
1781 | EFI_STATUS\r | |
1782 | EFIAPI\r | |
1783 | NetLibDefaultUnload (\r | |
1784 | IN EFI_HANDLE ImageHandle\r | |
1785 | )\r | |
1786 | {\r | |
1787 | EFI_STATUS Status;\r | |
1788 | EFI_HANDLE *DeviceHandleBuffer;\r | |
1789 | UINTN DeviceHandleCount;\r | |
1790 | UINTN Index;\r | |
6879581d | 1791 | UINTN Index2;\r |
da1d0201 | 1792 | EFI_DRIVER_BINDING_PROTOCOL *DriverBinding;\r |
1793 | EFI_COMPONENT_NAME_PROTOCOL *ComponentName;\r | |
3012ce5c | 1794 | EFI_COMPONENT_NAME2_PROTOCOL *ComponentName2;\r |
da1d0201 | 1795 | \r |
1796 | //\r | |
1797 | // Get the list of all the handles in the handle database.\r | |
1798 | // If there is an error getting the list, then the unload\r | |
1799 | // operation fails.\r | |
1800 | //\r | |
1801 | Status = gBS->LocateHandleBuffer (\r | |
1802 | AllHandles,\r | |
1803 | NULL,\r | |
1804 | NULL,\r | |
1805 | &DeviceHandleCount,\r | |
1806 | &DeviceHandleBuffer\r | |
1807 | );\r | |
1808 | \r | |
1809 | if (EFI_ERROR (Status)) {\r | |
1810 | return Status;\r | |
1811 | }\r | |
1812 | \r | |
da1d0201 | 1813 | for (Index = 0; Index < DeviceHandleCount; Index++) {\r |
1814 | Status = gBS->HandleProtocol (\r | |
1815 | DeviceHandleBuffer[Index],\r | |
1816 | &gEfiDriverBindingProtocolGuid,\r | |
1817 | (VOID **) &DriverBinding\r | |
1818 | );\r | |
da1d0201 | 1819 | if (EFI_ERROR (Status)) {\r |
1820 | continue;\r | |
1821 | }\r | |
1822 | \r | |
1823 | if (DriverBinding->ImageHandle != ImageHandle) {\r | |
1824 | continue;\r | |
1825 | }\r | |
6879581d | 1826 | \r |
1827 | //\r | |
1828 | // Disconnect the driver specified by ImageHandle from all\r | |
1829 | // the devices in the handle database.\r | |
1830 | //\r | |
1831 | for (Index2 = 0; Index2 < DeviceHandleCount; Index2++) {\r | |
1832 | Status = gBS->DisconnectController (\r | |
1833 | DeviceHandleBuffer[Index2],\r | |
1834 | DriverBinding->DriverBindingHandle,\r | |
1835 | NULL\r | |
1836 | );\r | |
1837 | }\r | |
1838 | \r | |
1839 | //\r | |
1840 | // Uninstall all the protocols installed in the driver entry point\r | |
1841 | // \r | |
da1d0201 | 1842 | gBS->UninstallProtocolInterface (\r |
6879581d | 1843 | DriverBinding->DriverBindingHandle,\r |
da1d0201 | 1844 | &gEfiDriverBindingProtocolGuid,\r |
1845 | DriverBinding\r | |
1846 | );\r | |
6879581d | 1847 | \r |
da1d0201 | 1848 | Status = gBS->HandleProtocol (\r |
1849 | DeviceHandleBuffer[Index],\r | |
1850 | &gEfiComponentNameProtocolGuid,\r | |
1851 | (VOID **) &ComponentName\r | |
1852 | );\r | |
1853 | if (!EFI_ERROR (Status)) {\r | |
1854 | gBS->UninstallProtocolInterface (\r | |
6879581d | 1855 | DriverBinding->DriverBindingHandle,\r |
da1d0201 | 1856 | &gEfiComponentNameProtocolGuid,\r |
1857 | ComponentName\r | |
1858 | );\r | |
1859 | }\r | |
1860 | \r | |
1861 | Status = gBS->HandleProtocol (\r | |
1862 | DeviceHandleBuffer[Index],\r | |
3012ce5c | 1863 | &gEfiComponentName2ProtocolGuid,\r |
1864 | (VOID **) &ComponentName2\r | |
da1d0201 | 1865 | );\r |
da1d0201 | 1866 | if (!EFI_ERROR (Status)) {\r |
1867 | gBS->UninstallProtocolInterface (\r | |
6879581d | 1868 | DriverBinding->DriverBindingHandle,\r |
3012ce5c | 1869 | &gEfiComponentName2ProtocolGuid,\r |
1870 | ComponentName2\r | |
1871 | );\r | |
da1d0201 | 1872 | }\r |
1873 | }\r | |
1874 | \r | |
1875 | //\r | |
1876 | // Free the buffer containing the list of handles from the handle database\r | |
1877 | //\r | |
1878 | if (DeviceHandleBuffer != NULL) {\r | |
1879 | gBS->FreePool (DeviceHandleBuffer);\r | |
1880 | }\r | |
1881 | \r | |
1882 | return EFI_SUCCESS;\r | |
1883 | }\r | |
1884 | \r | |
1885 | \r | |
1886 | \r | |
1887 | /**\r | |
1888 | Create a child of the service that is identified by ServiceBindingGuid.\r | |
1204fe83 | 1889 | \r |
b9008c87 | 1890 | Get the ServiceBinding Protocol first, then use it to create a child.\r |
da1d0201 | 1891 | \r |
b9008c87 | 1892 | If ServiceBindingGuid is NULL, then ASSERT().\r |
1893 | If ChildHandle is NULL, then ASSERT().\r | |
1204fe83 | 1894 | \r |
3e7104c2 | 1895 | @param[in] Controller The controller which has the service installed.\r |
1896 | @param[in] Image The image handle used to open service.\r | |
1897 | @param[in] ServiceBindingGuid The service's Guid.\r | |
8f5e6151 | 1898 | @param[in, out] ChildHandle The handle to receive the create child.\r |
da1d0201 | 1899 | \r |
1900 | @retval EFI_SUCCESS The child is successfully created.\r | |
1901 | @retval Others Failed to create the child.\r | |
1902 | \r | |
1903 | **/\r | |
1904 | EFI_STATUS\r | |
7b414b4e | 1905 | EFIAPI\r |
da1d0201 | 1906 | NetLibCreateServiceChild (\r |
1907 | IN EFI_HANDLE Controller,\r | |
1908 | IN EFI_HANDLE Image,\r | |
1909 | IN EFI_GUID *ServiceBindingGuid,\r | |
3e7104c2 | 1910 | IN OUT EFI_HANDLE *ChildHandle\r |
da1d0201 | 1911 | )\r |
1912 | {\r | |
1913 | EFI_STATUS Status;\r | |
1914 | EFI_SERVICE_BINDING_PROTOCOL *Service;\r | |
1915 | \r | |
1916 | \r | |
1917 | ASSERT ((ServiceBindingGuid != NULL) && (ChildHandle != NULL));\r | |
1918 | \r | |
1919 | //\r | |
1920 | // Get the ServiceBinding Protocol\r | |
1921 | //\r | |
1922 | Status = gBS->OpenProtocol (\r | |
1923 | Controller,\r | |
1924 | ServiceBindingGuid,\r | |
1925 | (VOID **) &Service,\r | |
1926 | Image,\r | |
1927 | Controller,\r | |
1928 | EFI_OPEN_PROTOCOL_GET_PROTOCOL\r | |
1929 | );\r | |
1930 | \r | |
1931 | if (EFI_ERROR (Status)) {\r | |
1932 | return Status;\r | |
1933 | }\r | |
1934 | \r | |
1935 | //\r | |
1936 | // Create a child\r | |
1937 | //\r | |
1938 | Status = Service->CreateChild (Service, ChildHandle);\r | |
1939 | return Status;\r | |
1940 | }\r | |
1941 | \r | |
1942 | \r | |
1943 | /**\r | |
75dce340 | 1944 | Destroy a child of the service that is identified by ServiceBindingGuid.\r |
1204fe83 | 1945 | \r |
b9008c87 | 1946 | Get the ServiceBinding Protocol first, then use it to destroy a child.\r |
1204fe83 | 1947 | \r |
b9008c87 | 1948 | If ServiceBindingGuid is NULL, then ASSERT().\r |
1204fe83 | 1949 | \r |
3e7104c2 | 1950 | @param[in] Controller The controller which has the service installed.\r |
1951 | @param[in] Image The image handle used to open service.\r | |
1952 | @param[in] ServiceBindingGuid The service's Guid.\r | |
75dce340 | 1953 | @param[in] ChildHandle The child to destroy.\r |
da1d0201 | 1954 | \r |
75dce340 | 1955 | @retval EFI_SUCCESS The child is successfully destroyed.\r |
1956 | @retval Others Failed to destroy the child.\r | |
da1d0201 | 1957 | \r |
1958 | **/\r | |
1959 | EFI_STATUS\r | |
7b414b4e | 1960 | EFIAPI\r |
da1d0201 | 1961 | NetLibDestroyServiceChild (\r |
1962 | IN EFI_HANDLE Controller,\r | |
1963 | IN EFI_HANDLE Image,\r | |
1964 | IN EFI_GUID *ServiceBindingGuid,\r | |
1965 | IN EFI_HANDLE ChildHandle\r | |
1966 | )\r | |
1967 | {\r | |
1968 | EFI_STATUS Status;\r | |
1969 | EFI_SERVICE_BINDING_PROTOCOL *Service;\r | |
1970 | \r | |
1971 | ASSERT (ServiceBindingGuid != NULL);\r | |
1972 | \r | |
1973 | //\r | |
1974 | // Get the ServiceBinding Protocol\r | |
1975 | //\r | |
1976 | Status = gBS->OpenProtocol (\r | |
1977 | Controller,\r | |
1978 | ServiceBindingGuid,\r | |
1979 | (VOID **) &Service,\r | |
1980 | Image,\r | |
1981 | Controller,\r | |
1982 | EFI_OPEN_PROTOCOL_GET_PROTOCOL\r | |
1983 | );\r | |
1984 | \r | |
1985 | if (EFI_ERROR (Status)) {\r | |
1986 | return Status;\r | |
1987 | }\r | |
1988 | \r | |
1989 | //\r | |
75dce340 | 1990 | // destroy the child\r |
da1d0201 | 1991 | //\r |
1992 | Status = Service->DestroyChild (Service, ChildHandle);\r | |
1993 | return Status;\r | |
1994 | }\r | |
1995 | \r | |
779ae357 | 1996 | /**\r |
1997 | Get handle with Simple Network Protocol installed on it.\r | |
1998 | \r | |
1999 | There should be MNP Service Binding Protocol installed on the input ServiceHandle.\r | |
2000 | If Simple Network Protocol is already installed on the ServiceHandle, the\r | |
2001 | ServiceHandle will be returned. If SNP is not installed on the ServiceHandle,\r | |
2002 | try to find its parent handle with SNP installed.\r | |
2003 | \r | |
2004 | @param[in] ServiceHandle The handle where network service binding protocols are\r | |
2005 | installed on.\r | |
2006 | @param[out] Snp The pointer to store the address of the SNP instance.\r | |
2007 | This is an optional parameter that may be NULL.\r | |
2008 | \r | |
2009 | @return The SNP handle, or NULL if not found.\r | |
2010 | \r | |
2011 | **/\r | |
2012 | EFI_HANDLE\r | |
2013 | EFIAPI\r | |
2014 | NetLibGetSnpHandle (\r | |
2015 | IN EFI_HANDLE ServiceHandle,\r | |
2016 | OUT EFI_SIMPLE_NETWORK_PROTOCOL **Snp OPTIONAL\r | |
2017 | )\r | |
2018 | {\r | |
2019 | EFI_STATUS Status;\r | |
2020 | EFI_SIMPLE_NETWORK_PROTOCOL *SnpInstance;\r | |
2021 | EFI_DEVICE_PATH_PROTOCOL *DevicePath;\r | |
2022 | EFI_HANDLE SnpHandle;\r | |
2023 | \r | |
2024 | //\r | |
2025 | // Try to open SNP from ServiceHandle\r | |
2026 | //\r | |
2027 | SnpInstance = NULL;\r | |
2028 | Status = gBS->HandleProtocol (ServiceHandle, &gEfiSimpleNetworkProtocolGuid, (VOID **) &SnpInstance);\r | |
2029 | if (!EFI_ERROR (Status)) {\r | |
2030 | if (Snp != NULL) {\r | |
2031 | *Snp = SnpInstance;\r | |
2032 | }\r | |
2033 | return ServiceHandle;\r | |
2034 | }\r | |
2035 | \r | |
2036 | //\r | |
2037 | // Failed to open SNP, try to get SNP handle by LocateDevicePath()\r | |
2038 | //\r | |
2039 | DevicePath = DevicePathFromHandle (ServiceHandle);\r | |
2040 | if (DevicePath == NULL) {\r | |
2041 | return NULL;\r | |
2042 | }\r | |
2043 | \r | |
2044 | SnpHandle = NULL;\r | |
2045 | Status = gBS->LocateDevicePath (&gEfiSimpleNetworkProtocolGuid, &DevicePath, &SnpHandle);\r | |
2046 | if (EFI_ERROR (Status)) {\r | |
2047 | //\r | |
2048 | // Failed to find SNP handle\r | |
2049 | //\r | |
2050 | return NULL;\r | |
2051 | }\r | |
2052 | \r | |
2053 | Status = gBS->HandleProtocol (SnpHandle, &gEfiSimpleNetworkProtocolGuid, (VOID **) &SnpInstance);\r | |
2054 | if (!EFI_ERROR (Status)) {\r | |
2055 | if (Snp != NULL) {\r | |
2056 | *Snp = SnpInstance;\r | |
2057 | }\r | |
2058 | return SnpHandle;\r | |
2059 | }\r | |
2060 | \r | |
2061 | return NULL;\r | |
2062 | }\r | |
2063 | \r | |
2064 | /**\r | |
2065 | Retrieve VLAN ID of a VLAN device handle.\r | |
2066 | \r | |
2067 | Search VLAN device path node in Device Path of specified ServiceHandle and\r | |
2068 | return its VLAN ID. If no VLAN device path node found, then this ServiceHandle\r | |
2069 | is not a VLAN device handle, and 0 will be returned.\r | |
2070 | \r | |
2071 | @param[in] ServiceHandle The handle where network service binding protocols are\r | |
2072 | installed on.\r | |
2073 | \r | |
2074 | @return VLAN ID of the device handle, or 0 if not a VLAN device.\r | |
2075 | \r | |
2076 | **/\r | |
2077 | UINT16\r | |
2078 | EFIAPI\r | |
2079 | NetLibGetVlanId (\r | |
2080 | IN EFI_HANDLE ServiceHandle\r | |
2081 | )\r | |
2082 | {\r | |
2083 | EFI_DEVICE_PATH_PROTOCOL *DevicePath;\r | |
2084 | EFI_DEVICE_PATH_PROTOCOL *Node;\r | |
2085 | \r | |
2086 | DevicePath = DevicePathFromHandle (ServiceHandle);\r | |
2087 | if (DevicePath == NULL) {\r | |
2088 | return 0;\r | |
2089 | }\r | |
2090 | \r | |
2091 | Node = DevicePath;\r | |
2092 | while (!IsDevicePathEnd (Node)) {\r | |
2093 | if (Node->Type == MESSAGING_DEVICE_PATH && Node->SubType == MSG_VLAN_DP) {\r | |
2094 | return ((VLAN_DEVICE_PATH *) Node)->VlanId;\r | |
2095 | }\r | |
2096 | Node = NextDevicePathNode (Node);\r | |
2097 | }\r | |
2098 | \r | |
2099 | return 0;\r | |
2100 | }\r | |
2101 | \r | |
2102 | /**\r | |
2103 | Find VLAN device handle with specified VLAN ID.\r | |
2104 | \r | |
2105 | The VLAN child device handle is created by VLAN Config Protocol on ControllerHandle.\r | |
2106 | This function will append VLAN device path node to the parent device path,\r | |
2107 | and then use LocateDevicePath() to find the correct VLAN device handle.\r | |
2108 | \r | |
e2851998 | 2109 | @param[in] ControllerHandle The handle where network service binding protocols are\r |
779ae357 | 2110 | installed on.\r |
e2851998 | 2111 | @param[in] VlanId The configured VLAN ID for the VLAN device.\r |
779ae357 | 2112 | \r |
2113 | @return The VLAN device handle, or NULL if not found.\r | |
2114 | \r | |
2115 | **/\r | |
2116 | EFI_HANDLE\r | |
2117 | EFIAPI\r | |
2118 | NetLibGetVlanHandle (\r | |
2119 | IN EFI_HANDLE ControllerHandle,\r | |
2120 | IN UINT16 VlanId\r | |
2121 | )\r | |
2122 | {\r | |
2123 | EFI_DEVICE_PATH_PROTOCOL *ParentDevicePath;\r | |
2124 | EFI_DEVICE_PATH_PROTOCOL *VlanDevicePath;\r | |
2125 | EFI_DEVICE_PATH_PROTOCOL *DevicePath;\r | |
2126 | VLAN_DEVICE_PATH VlanNode;\r | |
2127 | EFI_HANDLE Handle;\r | |
2128 | \r | |
2129 | ParentDevicePath = DevicePathFromHandle (ControllerHandle);\r | |
2130 | if (ParentDevicePath == NULL) {\r | |
2131 | return NULL;\r | |
2132 | }\r | |
2133 | \r | |
2134 | //\r | |
2135 | // Construct VLAN device path\r | |
2136 | //\r | |
2137 | CopyMem (&VlanNode, &mNetVlanDevicePathTemplate, sizeof (VLAN_DEVICE_PATH));\r | |
2138 | VlanNode.VlanId = VlanId;\r | |
2139 | VlanDevicePath = AppendDevicePathNode (\r | |
2140 | ParentDevicePath,\r | |
2141 | (EFI_DEVICE_PATH_PROTOCOL *) &VlanNode\r | |
2142 | );\r | |
2143 | if (VlanDevicePath == NULL) {\r | |
2144 | return NULL;\r | |
2145 | }\r | |
2146 | \r | |
2147 | //\r | |
2148 | // Find VLAN device handle\r | |
2149 | //\r | |
2150 | Handle = NULL;\r | |
2151 | DevicePath = VlanDevicePath;\r | |
2152 | gBS->LocateDevicePath (\r | |
2153 | &gEfiDevicePathProtocolGuid,\r | |
2154 | &DevicePath,\r | |
2155 | &Handle\r | |
2156 | );\r | |
2157 | if (!IsDevicePathEnd (DevicePath)) {\r | |
2158 | //\r | |
2159 | // Device path is not exactly match\r | |
2160 | //\r | |
2161 | Handle = NULL;\r | |
2162 | }\r | |
2163 | \r | |
2164 | FreePool (VlanDevicePath);\r | |
2165 | return Handle;\r | |
2166 | }\r | |
da1d0201 | 2167 | \r |
2168 | /**\r | |
779ae357 | 2169 | Get MAC address associated with the network service handle.\r |
2170 | \r | |
2171 | There should be MNP Service Binding Protocol installed on the input ServiceHandle.\r | |
2172 | If SNP is installed on the ServiceHandle or its parent handle, MAC address will\r | |
2173 | be retrieved from SNP. If no SNP found, try to get SNP mode data use MNP.\r | |
2174 | \r | |
2175 | @param[in] ServiceHandle The handle where network service binding protocols are\r | |
2176 | installed on.\r | |
2177 | @param[out] MacAddress The pointer to store the returned MAC address.\r | |
2178 | @param[out] AddressSize The length of returned MAC address.\r | |
2179 | \r | |
2180 | @retval EFI_SUCCESS MAC address is returned successfully.\r | |
2181 | @retval Others Failed to get SNP mode data.\r | |
2182 | \r | |
2183 | **/\r | |
2184 | EFI_STATUS\r | |
2185 | EFIAPI\r | |
2186 | NetLibGetMacAddress (\r | |
2187 | IN EFI_HANDLE ServiceHandle,\r | |
2188 | OUT EFI_MAC_ADDRESS *MacAddress,\r | |
2189 | OUT UINTN *AddressSize\r | |
2190 | )\r | |
2191 | {\r | |
2192 | EFI_STATUS Status;\r | |
2193 | EFI_SIMPLE_NETWORK_PROTOCOL *Snp;\r | |
2194 | EFI_SIMPLE_NETWORK_MODE *SnpMode;\r | |
2195 | EFI_SIMPLE_NETWORK_MODE SnpModeData;\r | |
2196 | EFI_MANAGED_NETWORK_PROTOCOL *Mnp;\r | |
2197 | EFI_SERVICE_BINDING_PROTOCOL *MnpSb;\r | |
2198 | EFI_HANDLE *SnpHandle;\r | |
2199 | EFI_HANDLE MnpChildHandle;\r | |
2200 | \r | |
2201 | ASSERT (MacAddress != NULL);\r | |
2202 | ASSERT (AddressSize != NULL);\r | |
2203 | \r | |
2204 | //\r | |
2205 | // Try to get SNP handle\r | |
2206 | //\r | |
2207 | Snp = NULL;\r | |
2208 | SnpHandle = NetLibGetSnpHandle (ServiceHandle, &Snp);\r | |
2209 | if (SnpHandle != NULL) {\r | |
2210 | //\r | |
2211 | // SNP found, use it directly\r | |
2212 | //\r | |
2213 | SnpMode = Snp->Mode;\r | |
2214 | } else {\r | |
2215 | //\r | |
2216 | // Failed to get SNP handle, try to get MAC address from MNP\r | |
2217 | //\r | |
2218 | MnpChildHandle = NULL;\r | |
2219 | Status = gBS->HandleProtocol (\r | |
2220 | ServiceHandle,\r | |
2221 | &gEfiManagedNetworkServiceBindingProtocolGuid,\r | |
2222 | (VOID **) &MnpSb\r | |
2223 | );\r | |
2224 | if (EFI_ERROR (Status)) {\r | |
2225 | return Status;\r | |
2226 | }\r | |
2227 | \r | |
2228 | //\r | |
2229 | // Create a MNP child\r | |
2230 | //\r | |
2231 | Status = MnpSb->CreateChild (MnpSb, &MnpChildHandle);\r | |
2232 | if (EFI_ERROR (Status)) {\r | |
2233 | return Status;\r | |
2234 | }\r | |
2235 | \r | |
2236 | //\r | |
2237 | // Open MNP protocol\r | |
2238 | //\r | |
2239 | Status = gBS->HandleProtocol (\r | |
2240 | MnpChildHandle,\r | |
2241 | &gEfiManagedNetworkProtocolGuid,\r | |
2242 | (VOID **) &Mnp\r | |
2243 | );\r | |
2244 | if (EFI_ERROR (Status)) {\r | |
e20d6513 | 2245 | MnpSb->DestroyChild (MnpSb, MnpChildHandle);\r |
779ae357 | 2246 | return Status;\r |
2247 | }\r | |
da1d0201 | 2248 | \r |
779ae357 | 2249 | //\r |
2250 | // Try to get SNP mode from MNP\r | |
2251 | //\r | |
2252 | Status = Mnp->GetModeData (Mnp, NULL, &SnpModeData);\r | |
3ce454dd | 2253 | if (EFI_ERROR (Status) && (Status != EFI_NOT_STARTED)) {\r |
e20d6513 | 2254 | MnpSb->DestroyChild (MnpSb, MnpChildHandle);\r |
779ae357 | 2255 | return Status;\r |
2256 | }\r | |
2257 | SnpMode = &SnpModeData;\r | |
b9008c87 | 2258 | \r |
779ae357 | 2259 | //\r |
2260 | // Destroy the MNP child\r | |
2261 | //\r | |
2262 | MnpSb->DestroyChild (MnpSb, MnpChildHandle);\r | |
2263 | }\r | |
b9008c87 | 2264 | \r |
779ae357 | 2265 | *AddressSize = SnpMode->HwAddressSize;\r |
2266 | CopyMem (MacAddress->Addr, SnpMode->CurrentAddress.Addr, SnpMode->HwAddressSize);\r | |
2267 | \r | |
2268 | return EFI_SUCCESS;\r | |
2269 | }\r | |
2270 | \r | |
2271 | /**\r | |
2272 | Convert MAC address of the NIC associated with specified Service Binding Handle\r | |
2273 | to a unicode string. Callers are responsible for freeing the string storage.\r | |
2274 | \r | |
2275 | Locate simple network protocol associated with the Service Binding Handle and\r | |
2276 | get the mac address from SNP. Then convert the mac address into a unicode\r | |
2277 | string. It takes 2 unicode characters to represent a 1 byte binary buffer.\r | |
2278 | Plus one unicode character for the null-terminator.\r | |
2279 | \r | |
2280 | @param[in] ServiceHandle The handle where network service binding protocol is\r | |
3e7104c2 | 2281 | installed on.\r |
2282 | @param[in] ImageHandle The image handle used to act as the agent handle to\r | |
b00ed21a | 2283 | get the simple network protocol. This parameter is\r |
2284 | optional and may be NULL.\r | |
3e7104c2 | 2285 | @param[out] MacString The pointer to store the address of the string\r |
2286 | representation of the mac address.\r | |
1204fe83 | 2287 | \r |
3e7104c2 | 2288 | @retval EFI_SUCCESS Convert the mac address a unicode string successfully.\r |
da1d0201 | 2289 | @retval EFI_OUT_OF_RESOURCES There are not enough memory resource.\r |
3e7104c2 | 2290 | @retval Others Failed to open the simple network protocol.\r |
da1d0201 | 2291 | \r |
2292 | **/\r | |
2293 | EFI_STATUS\r | |
7b414b4e | 2294 | EFIAPI\r |
da1d0201 | 2295 | NetLibGetMacString (\r |
779ae357 | 2296 | IN EFI_HANDLE ServiceHandle,\r |
b00ed21a | 2297 | IN EFI_HANDLE ImageHandle, OPTIONAL\r |
3e7104c2 | 2298 | OUT CHAR16 **MacString\r |
da1d0201 | 2299 | )\r |
2300 | {\r | |
2301 | EFI_STATUS Status;\r | |
779ae357 | 2302 | EFI_MAC_ADDRESS MacAddress;\r |
1204fe83 | 2303 | UINT8 *HwAddress;\r |
779ae357 | 2304 | UINTN HwAddressSize;\r |
2305 | UINT16 VlanId;\r | |
2306 | CHAR16 *String;\r | |
da1d0201 | 2307 | UINTN Index;\r |
2308 | \r | |
779ae357 | 2309 | ASSERT (MacString != NULL);\r |
da1d0201 | 2310 | \r |
2311 | //\r | |
779ae357 | 2312 | // Get MAC address of the network device\r |
da1d0201 | 2313 | //\r |
779ae357 | 2314 | Status = NetLibGetMacAddress (ServiceHandle, &MacAddress, &HwAddressSize);\r |
da1d0201 | 2315 | if (EFI_ERROR (Status)) {\r |
2316 | return Status;\r | |
2317 | }\r | |
2318 | \r | |
da1d0201 | 2319 | //\r |
2320 | // It takes 2 unicode characters to represent a 1 byte binary buffer.\r | |
779ae357 | 2321 | // If VLAN is configured, it will need extra 5 characters like "\0005".\r |
da1d0201 | 2322 | // Plus one unicode character for the null-terminator.\r |
2323 | //\r | |
779ae357 | 2324 | String = AllocateZeroPool ((2 * HwAddressSize + 5 + 1) * sizeof (CHAR16));\r |
2325 | if (String == NULL) {\r | |
da1d0201 | 2326 | return EFI_OUT_OF_RESOURCES;\r |
2327 | }\r | |
779ae357 | 2328 | *MacString = String;\r |
da1d0201 | 2329 | \r |
2330 | //\r | |
779ae357 | 2331 | // Convert the MAC address into a unicode string.\r |
da1d0201 | 2332 | //\r |
779ae357 | 2333 | HwAddress = &MacAddress.Addr[0];\r |
2334 | for (Index = 0; Index < HwAddressSize; Index++) {\r | |
2335 | String += UnicodeValueToString (String, PREFIX_ZERO | RADIX_HEX, *(HwAddress++), 2);\r | |
da1d0201 | 2336 | }\r |
2337 | \r | |
779ae357 | 2338 | //\r |
2339 | // Append VLAN ID if any\r | |
2340 | //\r | |
2341 | VlanId = NetLibGetVlanId (ServiceHandle);\r | |
2342 | if (VlanId != 0) {\r | |
2343 | *String++ = L'\\';\r | |
2344 | String += UnicodeValueToString (String, PREFIX_ZERO | RADIX_HEX, VlanId, 4);\r | |
2345 | }\r | |
da1d0201 | 2346 | \r |
779ae357 | 2347 | //\r |
2348 | // Null terminate the Unicode string\r | |
2349 | //\r | |
2350 | *String = L'\0';\r | |
da1d0201 | 2351 | \r |
2352 | return EFI_SUCCESS;\r | |
2353 | }\r | |
2354 | \r | |
dd29f3ed | 2355 | /**\r |
2356 | Detect media status for specified network device.\r | |
2357 | \r | |
2358 | The underlying UNDI driver may or may not support reporting media status from\r | |
2359 | GET_STATUS command (PXE_STATFLAGS_GET_STATUS_NO_MEDIA_SUPPORTED). This routine\r | |
2360 | will try to invoke Snp->GetStatus() to get the media status: if media already\r | |
2361 | present, it return directly; if media not present, it will stop SNP and then\r | |
2362 | restart SNP to get the latest media status, this give chance to get the correct\r | |
2363 | media status for old UNDI driver which doesn't support reporting media status\r | |
2364 | from GET_STATUS command.\r | |
2365 | Note: there will be two limitations for current algorithm:\r | |
2366 | 1) for UNDI with this capability, in case of cable is not attached, there will\r | |
2367 | be an redundant Stop/Start() process;\r | |
3b1464d5 | 2368 | 2) for UNDI without this capability, in case that network cable is attached when\r |
2369 | Snp->Initialize() is invoked while network cable is unattached later,\r | |
2370 | NetLibDetectMedia() will report MediaPresent as TRUE, causing upper layer\r | |
2371 | apps to wait for timeout time.\r | |
dd29f3ed | 2372 | \r |
2373 | @param[in] ServiceHandle The handle where network service binding protocols are\r | |
2374 | installed on.\r | |
2375 | @param[out] MediaPresent The pointer to store the media status.\r | |
2376 | \r | |
2377 | @retval EFI_SUCCESS Media detection success.\r | |
2378 | @retval EFI_INVALID_PARAMETER ServiceHandle is not valid network device handle.\r | |
2379 | @retval EFI_UNSUPPORTED Network device does not support media detection.\r | |
2380 | @retval EFI_DEVICE_ERROR SNP is in unknown state.\r | |
2381 | \r | |
2382 | **/\r | |
2383 | EFI_STATUS\r | |
2384 | EFIAPI\r | |
2385 | NetLibDetectMedia (\r | |
2386 | IN EFI_HANDLE ServiceHandle,\r | |
2387 | OUT BOOLEAN *MediaPresent\r | |
2388 | )\r | |
2389 | {\r | |
2390 | EFI_STATUS Status;\r | |
2391 | EFI_HANDLE SnpHandle;\r | |
2392 | EFI_SIMPLE_NETWORK_PROTOCOL *Snp;\r | |
2393 | UINT32 InterruptStatus;\r | |
2394 | UINT32 OldState;\r | |
2395 | EFI_MAC_ADDRESS *MCastFilter;\r | |
2396 | UINT32 MCastFilterCount;\r | |
2397 | UINT32 EnableFilterBits;\r | |
2398 | UINT32 DisableFilterBits;\r | |
2399 | BOOLEAN ResetMCastFilters;\r | |
2400 | \r | |
2401 | ASSERT (MediaPresent != NULL);\r | |
2402 | \r | |
2403 | //\r | |
2404 | // Get SNP handle\r | |
2405 | //\r | |
2406 | Snp = NULL;\r | |
2407 | SnpHandle = NetLibGetSnpHandle (ServiceHandle, &Snp);\r | |
2408 | if (SnpHandle == NULL) {\r | |
2409 | return EFI_INVALID_PARAMETER;\r | |
2410 | }\r | |
2411 | \r | |
2412 | //\r | |
2413 | // Check whether SNP support media detection\r | |
2414 | //\r | |
2415 | if (!Snp->Mode->MediaPresentSupported) {\r | |
2416 | return EFI_UNSUPPORTED;\r | |
2417 | }\r | |
2418 | \r | |
2419 | //\r | |
2420 | // Invoke Snp->GetStatus() to refresh MediaPresent field in SNP mode data\r | |
2421 | //\r | |
2422 | Status = Snp->GetStatus (Snp, &InterruptStatus, NULL);\r | |
2423 | if (EFI_ERROR (Status)) {\r | |
2424 | return Status;\r | |
2425 | }\r | |
2426 | \r | |
2427 | if (Snp->Mode->MediaPresent) {\r | |
2428 | //\r | |
2429 | // Media is present, return directly\r | |
2430 | //\r | |
2431 | *MediaPresent = TRUE;\r | |
2432 | return EFI_SUCCESS;\r | |
2433 | }\r | |
2434 | \r | |
2435 | //\r | |
2436 | // Till now, GetStatus() report no media; while, in case UNDI not support\r | |
2437 | // reporting media status from GetStatus(), this media status may be incorrect.\r | |
2438 | // So, we will stop SNP and then restart it to get the correct media status.\r | |
2439 | //\r | |
2440 | OldState = Snp->Mode->State;\r | |
2441 | if (OldState >= EfiSimpleNetworkMaxState) {\r | |
2442 | return EFI_DEVICE_ERROR;\r | |
2443 | }\r | |
2444 | \r | |
2445 | MCastFilter = NULL;\r | |
2446 | \r | |
2447 | if (OldState == EfiSimpleNetworkInitialized) {\r | |
2448 | //\r | |
2449 | // SNP is already in use, need Shutdown/Stop and then Start/Initialize\r | |
2450 | //\r | |
2451 | \r | |
2452 | //\r | |
2453 | // Backup current SNP receive filter settings\r | |
2454 | //\r | |
2455 | EnableFilterBits = Snp->Mode->ReceiveFilterSetting;\r | |
2456 | DisableFilterBits = Snp->Mode->ReceiveFilterMask ^ EnableFilterBits;\r | |
2457 | \r | |
2458 | ResetMCastFilters = TRUE;\r | |
2459 | MCastFilterCount = Snp->Mode->MCastFilterCount;\r | |
2460 | if (MCastFilterCount != 0) {\r | |
2461 | MCastFilter = AllocateCopyPool (\r | |
2462 | MCastFilterCount * sizeof (EFI_MAC_ADDRESS),\r | |
2463 | Snp->Mode->MCastFilter\r | |
2464 | );\r | |
2465 | ASSERT (MCastFilter != NULL);\r | |
2466 | \r | |
2467 | ResetMCastFilters = FALSE;\r | |
2468 | }\r | |
2469 | \r | |
2470 | //\r | |
2471 | // Shutdown/Stop the simple network\r | |
2472 | //\r | |
2473 | Status = Snp->Shutdown (Snp);\r | |
2474 | if (!EFI_ERROR (Status)) {\r | |
2475 | Status = Snp->Stop (Snp);\r | |
2476 | }\r | |
2477 | if (EFI_ERROR (Status)) {\r | |
2478 | goto Exit;\r | |
2479 | }\r | |
2480 | \r | |
2481 | //\r | |
2482 | // Start/Initialize the simple network\r | |
2483 | //\r | |
2484 | Status = Snp->Start (Snp);\r | |
2485 | if (!EFI_ERROR (Status)) {\r | |
2486 | Status = Snp->Initialize (Snp, 0, 0);\r | |
2487 | }\r | |
2488 | if (EFI_ERROR (Status)) {\r | |
2489 | goto Exit;\r | |
2490 | }\r | |
2491 | \r | |
2492 | //\r | |
2493 | // Here we get the correct media status\r | |
2494 | //\r | |
2495 | *MediaPresent = Snp->Mode->MediaPresent;\r | |
2496 | \r | |
2497 | //\r | |
2498 | // Restore SNP receive filter settings\r | |
2499 | //\r | |
2500 | Status = Snp->ReceiveFilters (\r | |
2501 | Snp,\r | |
2502 | EnableFilterBits,\r | |
2503 | DisableFilterBits,\r | |
2504 | ResetMCastFilters,\r | |
2505 | MCastFilterCount,\r | |
2506 | MCastFilter\r | |
2507 | );\r | |
2508 | \r | |
2509 | if (MCastFilter != NULL) {\r | |
2510 | FreePool (MCastFilter);\r | |
2511 | }\r | |
2512 | \r | |
2513 | return Status;\r | |
2514 | }\r | |
2515 | \r | |
2516 | //\r | |
2517 | // SNP is not in use, it's in state of EfiSimpleNetworkStopped or EfiSimpleNetworkStarted\r | |
2518 | //\r | |
2519 | if (OldState == EfiSimpleNetworkStopped) {\r | |
2520 | //\r | |
2521 | // SNP not start yet, start it\r | |
2522 | //\r | |
2523 | Status = Snp->Start (Snp);\r | |
2524 | if (EFI_ERROR (Status)) {\r | |
2525 | goto Exit;\r | |
2526 | }\r | |
2527 | }\r | |
2528 | \r | |
2529 | //\r | |
2530 | // Initialize the simple network\r | |
2531 | //\r | |
2532 | Status = Snp->Initialize (Snp, 0, 0);\r | |
2533 | if (EFI_ERROR (Status)) {\r | |
2534 | Status = EFI_DEVICE_ERROR;\r | |
2535 | goto Exit;\r | |
2536 | }\r | |
2537 | \r | |
2538 | //\r | |
2539 | // Here we get the correct media status\r | |
2540 | //\r | |
2541 | *MediaPresent = Snp->Mode->MediaPresent;\r | |
2542 | \r | |
2543 | //\r | |
2544 | // Shut down the simple network\r | |
2545 | //\r | |
2546 | Snp->Shutdown (Snp);\r | |
2547 | \r | |
2548 | Exit:\r | |
2549 | if (OldState == EfiSimpleNetworkStopped) {\r | |
2550 | //\r | |
2551 | // Original SNP sate is Stopped, restore to original state\r | |
2552 | //\r | |
2553 | Snp->Stop (Snp);\r | |
2554 | }\r | |
2555 | \r | |
2556 | if (MCastFilter != NULL) {\r | |
2557 | FreePool (MCastFilter);\r | |
2558 | }\r | |
2559 | \r | |
2560 | return Status;\r | |
2561 | }\r | |
2562 | \r | |
da1d0201 | 2563 | /**\r |
2564 | Check the default address used by the IPv4 driver is static or dynamic (acquired\r | |
2565 | from DHCP).\r | |
2566 | \r | |
1204fe83 | 2567 | If the controller handle does not have the NIC Ip4 Config Protocol installed, the\r |
b9008c87 | 2568 | default address is static. If the EFI variable to save the configuration is not found,\r |
1204fe83 | 2569 | the default address is static. Otherwise, get the result from the EFI variable which\r |
b9008c87 | 2570 | saving the configuration.\r |
1204fe83 | 2571 | \r |
3e7104c2 | 2572 | @param[in] Controller The controller handle which has the NIC Ip4 Config Protocol\r |
2573 | relative with the default address to judge.\r | |
da1d0201 | 2574 | \r |
2575 | @retval TRUE If the default address is static.\r | |
2576 | @retval FALSE If the default address is acquired from DHCP.\r | |
2577 | \r | |
2578 | **/\r | |
da1d0201 | 2579 | BOOLEAN\r |
2580 | NetLibDefaultAddressIsStatic (\r | |
2581 | IN EFI_HANDLE Controller\r | |
2582 | )\r | |
2583 | {\r | |
63886849 | 2584 | EFI_STATUS Status;\r |
2585 | EFI_HII_CONFIG_ROUTING_PROTOCOL *HiiConfigRouting;\r | |
2586 | UINTN Len;\r | |
2587 | NIC_IP4_CONFIG_INFO *ConfigInfo;\r | |
2588 | BOOLEAN IsStatic;\r | |
2589 | EFI_STRING ConfigHdr;\r | |
2590 | EFI_STRING ConfigResp;\r | |
2591 | EFI_STRING AccessProgress;\r | |
2592 | EFI_STRING AccessResults;\r | |
2593 | EFI_STRING String;\r | |
1dc1b43f | 2594 | EFI_HANDLE ChildHandle;\r |
63886849 | 2595 | \r |
2596 | ConfigInfo = NULL;\r | |
2597 | ConfigHdr = NULL;\r | |
2598 | ConfigResp = NULL;\r | |
2599 | AccessProgress = NULL;\r | |
2600 | AccessResults = NULL;\r | |
2601 | IsStatic = TRUE;\r | |
2602 | \r | |
2603 | Status = gBS->LocateProtocol (\r | |
70b68990 | 2604 | &gEfiHiiConfigRoutingProtocolGuid,\r |
2605 | NULL,\r | |
2606 | (VOID **) &HiiConfigRouting\r | |
2607 | );\r | |
da1d0201 | 2608 | if (EFI_ERROR (Status)) {\r |
2609 | return TRUE;\r | |
2610 | }\r | |
2611 | \r | |
1dc1b43f | 2612 | Status = NetGetChildHandle (Controller, &ChildHandle);\r |
2613 | if (EFI_ERROR (Status)) {\r | |
2614 | return TRUE;\r | |
2615 | }\r | |
2616 | \r | |
63886849 | 2617 | //\r |
2618 | // Construct config request string header\r | |
2619 | //\r | |
1dc1b43f | 2620 | ConfigHdr = HiiConstructConfigHdr (&gEfiNicIp4ConfigVariableGuid, EFI_NIC_IP4_CONFIG_VARIABLE, ChildHandle);\r |
894d038a | 2621 | if (ConfigHdr == NULL) {\r |
2622 | return TRUE;\r | |
2623 | }\r | |
1204fe83 | 2624 | \r |
63886849 | 2625 | Len = StrLen (ConfigHdr);\r |
ce4106be | 2626 | ConfigResp = AllocateZeroPool ((Len + NIC_ITEM_CONFIG_SIZE * 2 + 100) * sizeof (CHAR16));\r |
63886849 | 2627 | if (ConfigResp == NULL) {\r |
2628 | goto ON_EXIT;\r | |
2629 | }\r | |
2630 | StrCpy (ConfigResp, ConfigHdr);\r | |
2631 | \r | |
2632 | String = ConfigResp + Len;\r | |
2633 | UnicodeSPrint (\r | |
1204fe83 | 2634 | String,\r |
2635 | (8 + 4 + 7 + 4 + 1) * sizeof (CHAR16),\r | |
2636 | L"&OFFSET=%04X&WIDTH=%04X",\r | |
2637 | OFFSET_OF (NIC_IP4_CONFIG_INFO, Source),\r | |
63886849 | 2638 | sizeof (UINT32)\r |
2639 | );\r | |
2640 | \r | |
2641 | Status = HiiConfigRouting->ExtractConfig (\r | |
2642 | HiiConfigRouting,\r | |
2643 | ConfigResp,\r | |
2644 | &AccessProgress,\r | |
2645 | &AccessResults\r | |
2646 | );\r | |
2647 | if (EFI_ERROR (Status)) {\r | |
2648 | goto ON_EXIT;\r | |
da1d0201 | 2649 | }\r |
2650 | \r | |
1dc1b43f | 2651 | ConfigInfo = AllocateZeroPool (NIC_ITEM_CONFIG_SIZE);\r |
da1d0201 | 2652 | if (ConfigInfo == NULL) {\r |
63886849 | 2653 | goto ON_EXIT;\r |
da1d0201 | 2654 | }\r |
2655 | \r | |
63886849 | 2656 | ConfigInfo->Source = IP4_CONFIG_SOURCE_STATIC;\r |
2657 | Len = NIC_ITEM_CONFIG_SIZE;\r | |
2658 | Status = HiiConfigRouting->ConfigToBlock (\r | |
2659 | HiiConfigRouting,\r | |
2660 | AccessResults,\r | |
2661 | (UINT8 *) ConfigInfo,\r | |
2662 | &Len,\r | |
2663 | &AccessProgress\r | |
2664 | );\r | |
da1d0201 | 2665 | if (EFI_ERROR (Status)) {\r |
2666 | goto ON_EXIT;\r | |
2667 | }\r | |
2668 | \r | |
2669 | IsStatic = (BOOLEAN) (ConfigInfo->Source == IP4_CONFIG_SOURCE_STATIC);\r | |
1204fe83 | 2670 | \r |
da1d0201 | 2671 | ON_EXIT:\r |
2672 | \r | |
63886849 | 2673 | if (AccessResults != NULL) {\r |
2674 | FreePool (AccessResults);\r | |
2675 | }\r | |
2676 | if (ConfigInfo != NULL) {\r | |
2677 | FreePool (ConfigInfo);\r | |
2678 | }\r | |
2679 | if (ConfigResp != NULL) {\r | |
2680 | FreePool (ConfigResp);\r | |
2681 | }\r | |
2682 | if (ConfigHdr != NULL) {\r | |
2683 | FreePool (ConfigHdr);\r | |
2684 | }\r | |
da1d0201 | 2685 | \r |
2686 | return IsStatic;\r | |
2687 | }\r | |
2688 | \r | |
2689 | /**\r | |
2690 | Create an IPv4 device path node.\r | |
1204fe83 | 2691 | \r |
b9008c87 | 2692 | The header type of IPv4 device path node is MESSAGING_DEVICE_PATH.\r |
2693 | The header subtype of IPv4 device path node is MSG_IPv4_DP.\r | |
b9008c87 | 2694 | Get other info from parameters to make up the whole IPv4 device path node.\r |
da1d0201 | 2695 | \r |
3e7104c2 | 2696 | @param[in, out] Node Pointer to the IPv4 device path node.\r |
f6b7393c | 2697 | @param[in] Controller The controller handle.\r |
3e7104c2 | 2698 | @param[in] LocalIp The local IPv4 address.\r |
2699 | @param[in] LocalPort The local port.\r | |
2700 | @param[in] RemoteIp The remote IPv4 address.\r | |
2701 | @param[in] RemotePort The remote port.\r | |
2702 | @param[in] Protocol The protocol type in the IP header.\r | |
2703 | @param[in] UseDefaultAddress Whether this instance is using default address or not.\r | |
da1d0201 | 2704 | \r |
da1d0201 | 2705 | **/\r |
2706 | VOID\r | |
7b414b4e | 2707 | EFIAPI\r |
da1d0201 | 2708 | NetLibCreateIPv4DPathNode (\r |
2709 | IN OUT IPv4_DEVICE_PATH *Node,\r | |
2710 | IN EFI_HANDLE Controller,\r | |
2711 | IN IP4_ADDR LocalIp,\r | |
2712 | IN UINT16 LocalPort,\r | |
2713 | IN IP4_ADDR RemoteIp,\r | |
2714 | IN UINT16 RemotePort,\r | |
2715 | IN UINT16 Protocol,\r | |
2716 | IN BOOLEAN UseDefaultAddress\r | |
2717 | )\r | |
2718 | {\r | |
2719 | Node->Header.Type = MESSAGING_DEVICE_PATH;\r | |
2720 | Node->Header.SubType = MSG_IPv4_DP;\r | |
501793fa | 2721 | SetDevicePathNodeLength (&Node->Header, sizeof (IPv4_DEVICE_PATH));\r |
da1d0201 | 2722 | \r |
e48e37fc | 2723 | CopyMem (&Node->LocalIpAddress, &LocalIp, sizeof (EFI_IPv4_ADDRESS));\r |
2724 | CopyMem (&Node->RemoteIpAddress, &RemoteIp, sizeof (EFI_IPv4_ADDRESS));\r | |
da1d0201 | 2725 | \r |
2726 | Node->LocalPort = LocalPort;\r | |
2727 | Node->RemotePort = RemotePort;\r | |
2728 | \r | |
2729 | Node->Protocol = Protocol;\r | |
2730 | \r | |
2731 | if (!UseDefaultAddress) {\r | |
2732 | Node->StaticIpAddress = TRUE;\r | |
2733 | } else {\r | |
2734 | Node->StaticIpAddress = NetLibDefaultAddressIsStatic (Controller);\r | |
2735 | }\r | |
501793fa RN |
2736 | \r |
2737 | //\r | |
2738 | // Set the Gateway IP address to default value 0:0:0:0.\r | |
2739 | // Set the Subnet mask to default value 255:255:255:0.\r | |
2740 | //\r | |
2741 | ZeroMem (&Node->GatewayIpAddress, sizeof (EFI_IPv4_ADDRESS));\r | |
2742 | SetMem (&Node->SubnetMask, sizeof (EFI_IPv4_ADDRESS), 0xff);\r | |
2743 | Node->SubnetMask.Addr[3] = 0;\r | |
da1d0201 | 2744 | }\r |
2745 | \r | |
f6b7393c | 2746 | /**\r |
2747 | Create an IPv6 device path node.\r | |
1204fe83 | 2748 | \r |
f6b7393c | 2749 | The header type of IPv6 device path node is MESSAGING_DEVICE_PATH.\r |
2750 | The header subtype of IPv6 device path node is MSG_IPv6_DP.\r | |
2751 | Get other info from parameters to make up the whole IPv6 device path node.\r | |
2752 | \r | |
2753 | @param[in, out] Node Pointer to the IPv6 device path node.\r | |
2754 | @param[in] Controller The controller handle.\r | |
2755 | @param[in] LocalIp The local IPv6 address.\r | |
2756 | @param[in] LocalPort The local port.\r | |
2757 | @param[in] RemoteIp The remote IPv6 address.\r | |
2758 | @param[in] RemotePort The remote port.\r | |
2759 | @param[in] Protocol The protocol type in the IP header.\r | |
2760 | \r | |
2761 | **/\r | |
2762 | VOID\r | |
2763 | EFIAPI\r | |
2764 | NetLibCreateIPv6DPathNode (\r | |
2765 | IN OUT IPv6_DEVICE_PATH *Node,\r | |
2766 | IN EFI_HANDLE Controller,\r | |
2767 | IN EFI_IPv6_ADDRESS *LocalIp,\r | |
2768 | IN UINT16 LocalPort,\r | |
2769 | IN EFI_IPv6_ADDRESS *RemoteIp,\r | |
2770 | IN UINT16 RemotePort,\r | |
2771 | IN UINT16 Protocol\r | |
2772 | )\r | |
2773 | {\r | |
2774 | Node->Header.Type = MESSAGING_DEVICE_PATH;\r | |
2775 | Node->Header.SubType = MSG_IPv6_DP;\r | |
2776 | SetDevicePathNodeLength (&Node->Header, sizeof (IPv6_DEVICE_PATH));\r | |
2777 | \r | |
2778 | CopyMem (&Node->LocalIpAddress, LocalIp, sizeof (EFI_IPv6_ADDRESS));\r | |
2779 | CopyMem (&Node->RemoteIpAddress, RemoteIp, sizeof (EFI_IPv6_ADDRESS));\r | |
2780 | \r | |
2781 | Node->LocalPort = LocalPort;\r | |
2782 | Node->RemotePort = RemotePort;\r | |
2783 | \r | |
2784 | Node->Protocol = Protocol;\r | |
501793fa RN |
2785 | \r |
2786 | //\r | |
2787 | // Set default value to IPAddressOrigin, PrefixLength.\r | |
2788 | // Set the Gateway IP address to unspecified address.\r | |
2789 | //\r | |
2790 | Node->IpAddressOrigin = 0;\r | |
2791 | Node->PrefixLength = IP6_PREFIX_LENGTH;\r | |
2792 | ZeroMem (&Node->GatewayIpAddress, sizeof (EFI_IPv6_ADDRESS));\r | |
f6b7393c | 2793 | }\r |
da1d0201 | 2794 | \r |
2795 | /**\r | |
2796 | Find the UNDI/SNP handle from controller and protocol GUID.\r | |
1204fe83 | 2797 | \r |
da1d0201 | 2798 | For example, IP will open a MNP child to transmit/receive\r |
2799 | packets, when MNP is stopped, IP should also be stopped. IP\r | |
2800 | needs to find its own private data which is related the IP's\r | |
2801 | service binding instance that is install on UNDI/SNP handle.\r | |
2802 | Now, the controller is either a MNP or ARP child handle. But\r | |
2803 | IP opens these handle BY_DRIVER, use that info, we can get the\r | |
2804 | UNDI/SNP handle.\r | |
2805 | \r | |
3e7104c2 | 2806 | @param[in] Controller Then protocol handle to check.\r |
2807 | @param[in] ProtocolGuid The protocol that is related with the handle.\r | |
da1d0201 | 2808 | \r |
3e7104c2 | 2809 | @return The UNDI/SNP handle or NULL for errors.\r |
da1d0201 | 2810 | \r |
2811 | **/\r | |
2812 | EFI_HANDLE\r | |
7b414b4e | 2813 | EFIAPI\r |
da1d0201 | 2814 | NetLibGetNicHandle (\r |
2815 | IN EFI_HANDLE Controller,\r | |
2816 | IN EFI_GUID *ProtocolGuid\r | |
2817 | )\r | |
2818 | {\r | |
2819 | EFI_OPEN_PROTOCOL_INFORMATION_ENTRY *OpenBuffer;\r | |
2820 | EFI_HANDLE Handle;\r | |
2821 | EFI_STATUS Status;\r | |
2822 | UINTN OpenCount;\r | |
2823 | UINTN Index;\r | |
2824 | \r | |
2825 | Status = gBS->OpenProtocolInformation (\r | |
2826 | Controller,\r | |
2827 | ProtocolGuid,\r | |
2828 | &OpenBuffer,\r | |
2829 | &OpenCount\r | |
2830 | );\r | |
2831 | \r | |
2832 | if (EFI_ERROR (Status)) {\r | |
2833 | return NULL;\r | |
2834 | }\r | |
2835 | \r | |
2836 | Handle = NULL;\r | |
2837 | \r | |
2838 | for (Index = 0; Index < OpenCount; Index++) {\r | |
e2851998 | 2839 | if ((OpenBuffer[Index].Attributes & EFI_OPEN_PROTOCOL_BY_DRIVER) != 0) {\r |
da1d0201 | 2840 | Handle = OpenBuffer[Index].ControllerHandle;\r |
2841 | break;\r | |
2842 | }\r | |
2843 | }\r | |
2844 | \r | |
2845 | gBS->FreePool (OpenBuffer);\r | |
2846 | return Handle;\r | |
2847 | }\r | |
e4ef0031 | 2848 | \r |
2849 | /**\r | |
2850 | Convert one Null-terminated ASCII string (decimal dotted) to EFI_IPv4_ADDRESS.\r | |
2851 | \r | |
2852 | @param[in] String The pointer to the Ascii string.\r | |
2853 | @param[out] Ip4Address The pointer to the converted IPv4 address.\r | |
2854 | \r | |
dd29f3ed | 2855 | @retval EFI_SUCCESS Convert to IPv4 address successfully.\r |
e4ef0031 | 2856 | @retval EFI_INVALID_PARAMETER The string is mal-formated or Ip4Address is NULL.\r |
2857 | \r | |
2858 | **/\r | |
2859 | EFI_STATUS\r | |
e798cd87 | 2860 | EFIAPI\r |
e4ef0031 | 2861 | NetLibAsciiStrToIp4 (\r |
2862 | IN CONST CHAR8 *String,\r | |
2863 | OUT EFI_IPv4_ADDRESS *Ip4Address\r | |
2864 | )\r | |
2865 | {\r | |
2866 | UINT8 Index;\r | |
2867 | CHAR8 *Ip4Str;\r | |
2868 | CHAR8 *TempStr;\r | |
2869 | UINTN NodeVal;\r | |
2870 | \r | |
2871 | if ((String == NULL) || (Ip4Address == NULL)) {\r | |
2872 | return EFI_INVALID_PARAMETER;\r | |
2873 | }\r | |
2874 | \r | |
2875 | Ip4Str = (CHAR8 *) String;\r | |
2876 | \r | |
2877 | for (Index = 0; Index < 4; Index++) {\r | |
2878 | TempStr = Ip4Str;\r | |
2879 | \r | |
2880 | while ((*Ip4Str != '\0') && (*Ip4Str != '.')) {\r | |
2881 | Ip4Str++;\r | |
2882 | }\r | |
2883 | \r | |
2884 | //\r | |
2885 | // The IPv4 address is X.X.X.X\r | |
2886 | //\r | |
2887 | if (*Ip4Str == '.') {\r | |
2888 | if (Index == 3) {\r | |
2889 | return EFI_INVALID_PARAMETER;\r | |
2890 | }\r | |
2891 | } else {\r | |
2892 | if (Index != 3) {\r | |
2893 | return EFI_INVALID_PARAMETER;\r | |
2894 | }\r | |
2895 | }\r | |
2896 | \r | |
9b6f044a | 2897 | //\r |
2898 | // Convert the string to IPv4 address. AsciiStrDecimalToUintn stops at the\r | |
dd29f3ed | 2899 | // first character that is not a valid decimal character, '.' or '\0' here.\r |
9b6f044a | 2900 | //\r |
e4ef0031 | 2901 | NodeVal = AsciiStrDecimalToUintn (TempStr);\r |
2902 | if (NodeVal > 0xFF) {\r | |
2903 | return EFI_INVALID_PARAMETER;\r | |
2904 | }\r | |
2905 | \r | |
2906 | Ip4Address->Addr[Index] = (UINT8) NodeVal;\r | |
2907 | \r | |
2908 | Ip4Str++;\r | |
2909 | }\r | |
2910 | \r | |
2911 | return EFI_SUCCESS;\r | |
2912 | }\r | |
2913 | \r | |
2914 | \r | |
2915 | /**\r | |
2916 | Convert one Null-terminated ASCII string to EFI_IPv6_ADDRESS. The format of the\r | |
2917 | string is defined in RFC 4291 - Text Pepresentation of Addresses.\r | |
2918 | \r | |
2919 | @param[in] String The pointer to the Ascii string.\r | |
2920 | @param[out] Ip6Address The pointer to the converted IPv6 address.\r | |
2921 | \r | |
dd29f3ed | 2922 | @retval EFI_SUCCESS Convert to IPv6 address successfully.\r |
e4ef0031 | 2923 | @retval EFI_INVALID_PARAMETER The string is mal-formated or Ip6Address is NULL.\r |
2924 | \r | |
2925 | **/\r | |
2926 | EFI_STATUS\r | |
e798cd87 | 2927 | EFIAPI\r |
e4ef0031 | 2928 | NetLibAsciiStrToIp6 (\r |
2929 | IN CONST CHAR8 *String,\r | |
2930 | OUT EFI_IPv6_ADDRESS *Ip6Address\r | |
2931 | )\r | |
2932 | {\r | |
2933 | UINT8 Index;\r | |
2934 | CHAR8 *Ip6Str;\r | |
2935 | CHAR8 *TempStr;\r | |
2936 | CHAR8 *TempStr2;\r | |
2937 | UINT8 NodeCnt;\r | |
2938 | UINT8 TailNodeCnt;\r | |
2939 | UINT8 AllowedCnt;\r | |
2940 | UINTN NodeVal;\r | |
2941 | BOOLEAN Short;\r | |
2942 | BOOLEAN Update;\r | |
77545563 | 2943 | BOOLEAN LeadZero;\r |
2944 | UINT8 LeadZeroCnt;\r | |
2945 | UINT8 Cnt;\r | |
e4ef0031 | 2946 | \r |
2947 | if ((String == NULL) || (Ip6Address == NULL)) {\r | |
2948 | return EFI_INVALID_PARAMETER;\r | |
2949 | }\r | |
2950 | \r | |
77545563 | 2951 | Ip6Str = (CHAR8 *) String;\r |
2952 | AllowedCnt = 6;\r | |
2953 | LeadZeroCnt = 0;\r | |
e4ef0031 | 2954 | \r |
2955 | //\r | |
2956 | // An IPv6 address leading with : looks strange.\r | |
2957 | //\r | |
2958 | if (*Ip6Str == ':') {\r | |
2959 | if (*(Ip6Str + 1) != ':') {\r | |
2960 | return EFI_INVALID_PARAMETER;\r | |
2961 | } else {\r | |
2962 | AllowedCnt = 7;\r | |
dd29f3ed | 2963 | }\r |
e4ef0031 | 2964 | }\r |
2965 | \r | |
2966 | ZeroMem (Ip6Address, sizeof (EFI_IPv6_ADDRESS));\r | |
2967 | \r | |
2968 | NodeCnt = 0;\r | |
2969 | TailNodeCnt = 0;\r | |
2970 | Short = FALSE;\r | |
2971 | Update = FALSE;\r | |
77545563 | 2972 | LeadZero = FALSE;\r |
e4ef0031 | 2973 | \r |
9b6f044a | 2974 | for (Index = 0; Index < 15; Index = (UINT8) (Index + 2)) {\r |
e4ef0031 | 2975 | TempStr = Ip6Str;\r |
2976 | \r | |
2977 | while ((*Ip6Str != '\0') && (*Ip6Str != ':')) {\r | |
2978 | Ip6Str++;\r | |
2979 | }\r | |
2980 | \r | |
2981 | if ((*Ip6Str == '\0') && (Index != 14)) {\r | |
2982 | return EFI_INVALID_PARAMETER;\r | |
2983 | }\r | |
2984 | \r | |
2985 | if (*Ip6Str == ':') {\r | |
2986 | if (*(Ip6Str + 1) == ':') {\r | |
77545563 | 2987 | if ((NodeCnt > 6) || \r |
2988 | ((*(Ip6Str + 2) != '\0') && (AsciiStrHexToUintn (Ip6Str + 2) == 0))) {\r | |
e4ef0031 | 2989 | //\r |
2990 | // ::0 looks strange. report error to user.\r | |
2991 | //\r | |
2992 | return EFI_INVALID_PARAMETER;\r | |
dd29f3ed | 2993 | }\r |
77545563 | 2994 | if ((NodeCnt == 6) && (*(Ip6Str + 2) != '\0') && \r |
2995 | (AsciiStrHexToUintn (Ip6Str + 2) != 0)) {\r | |
2996 | return EFI_INVALID_PARAMETER;\r | |
2997 | }\r | |
e4ef0031 | 2998 | \r |
2999 | //\r | |
3000 | // Skip the abbreviation part of IPv6 address.\r | |
3001 | //\r | |
3002 | TempStr2 = Ip6Str + 2;\r | |
3003 | while ((*TempStr2 != '\0')) {\r | |
3004 | if (*TempStr2 == ':') {\r | |
3005 | if (*(TempStr2 + 1) == ':') {\r | |
3006 | //\r | |
3007 | // :: can only appear once in IPv6 address.\r | |
3008 | //\r | |
3009 | return EFI_INVALID_PARAMETER;\r | |
3010 | }\r | |
dd29f3ed | 3011 | \r |
e4ef0031 | 3012 | TailNodeCnt++;\r |
3013 | if (TailNodeCnt >= (AllowedCnt - NodeCnt)) {\r | |
3014 | //\r | |
3015 | // :: indicates one or more groups of 16 bits of zeros.\r | |
3016 | //\r | |
3017 | return EFI_INVALID_PARAMETER;\r | |
3018 | }\r | |
3019 | }\r | |
3020 | \r | |
3021 | TempStr2++;\r | |
dd29f3ed | 3022 | }\r |
e4ef0031 | 3023 | \r |
3024 | Short = TRUE;\r | |
3025 | Update = TRUE;\r | |
3026 | \r | |
3027 | Ip6Str = Ip6Str + 2;\r | |
3028 | } else {\r | |
77545563 | 3029 | if (*(Ip6Str + 1) == '\0') {\r |
3030 | return EFI_INVALID_PARAMETER;\r | |
3031 | }\r | |
e4ef0031 | 3032 | Ip6Str++;\r |
3033 | NodeCnt++;\r | |
3034 | if ((Short && (NodeCnt > 6)) || (!Short && (NodeCnt > 7))) {\r | |
3035 | //\r | |
3036 | // There are more than 8 groups of 16 bits of zeros.\r | |
3037 | //\r | |
3038 | return EFI_INVALID_PARAMETER;\r | |
3039 | }\r | |
dd29f3ed | 3040 | }\r |
3041 | }\r | |
e4ef0031 | 3042 | \r |
3043 | //\r | |
9b6f044a | 3044 | // Convert the string to IPv6 address. AsciiStrHexToUintn stops at the first\r |
dd29f3ed | 3045 | // character that is not a valid hexadecimal character, ':' or '\0' here.\r |
e4ef0031 | 3046 | //\r |
3047 | NodeVal = AsciiStrHexToUintn (TempStr);\r | |
3048 | if ((NodeVal > 0xFFFF) || (Index > 14)) {\r | |
3049 | return EFI_INVALID_PARAMETER;\r | |
3050 | }\r | |
77545563 | 3051 | if (NodeVal != 0) {\r |
3052 | if ((*TempStr == '0') && \r | |
3053 | ((*(TempStr + 2) == ':') || (*(TempStr + 3) == ':') || \r | |
3054 | (*(TempStr + 2) == '\0') || (*(TempStr + 3) == '\0'))) {\r | |
3055 | return EFI_INVALID_PARAMETER;\r | |
3056 | }\r | |
3057 | if ((*TempStr == '0') && (*(TempStr + 4) != '\0') && \r | |
3058 | (*(TempStr + 4) != ':')) { \r | |
3059 | return EFI_INVALID_PARAMETER;\r | |
3060 | }\r | |
3061 | } else {\r | |
3062 | if (((*TempStr == '0') && (*(TempStr + 1) == '0') && \r | |
3063 | ((*(TempStr + 2) == ':') || (*(TempStr + 2) == '\0'))) ||\r | |
3064 | ((*TempStr == '0') && (*(TempStr + 1) == '0') && (*(TempStr + 2) == '0') && \r | |
3065 | ((*(TempStr + 3) == ':') || (*(TempStr + 3) == '\0')))) {\r | |
3066 | return EFI_INVALID_PARAMETER;\r | |
3067 | }\r | |
3068 | }\r | |
3069 | \r | |
3070 | Cnt = 0;\r | |
3071 | while ((TempStr[Cnt] != ':') && (TempStr[Cnt] != '\0')) {\r | |
3072 | Cnt++; \r | |
3073 | }\r | |
3074 | if (LeadZeroCnt == 0) {\r | |
3075 | if ((Cnt == 4) && (*TempStr == '0')) {\r | |
3076 | LeadZero = TRUE;\r | |
3077 | LeadZeroCnt++;\r | |
3078 | }\r | |
3079 | if ((Cnt != 0) && (Cnt < 4)) {\r | |
3080 | LeadZero = FALSE;\r | |
3081 | LeadZeroCnt++;\r | |
3082 | }\r | |
3083 | } else {\r | |
3af91e23 | 3084 | if ((Cnt == 4) && (*TempStr == '0') && !LeadZero) {\r |
77545563 | 3085 | return EFI_INVALID_PARAMETER;\r |
3086 | }\r | |
3af91e23 | 3087 | if ((Cnt != 0) && (Cnt < 4) && LeadZero) {\r |
77545563 | 3088 | return EFI_INVALID_PARAMETER;\r |
3089 | }\r | |
3090 | } \r | |
e4ef0031 | 3091 | \r |
3092 | Ip6Address->Addr[Index] = (UINT8) (NodeVal >> 8);\r | |
3093 | Ip6Address->Addr[Index + 1] = (UINT8) (NodeVal & 0xFF);\r | |
3094 | \r | |
3095 | //\r | |
3096 | // Skip the groups of zeros by ::\r | |
3097 | //\r | |
3098 | if (Short && Update) {\r | |
3099 | Index = (UINT8) (16 - (TailNodeCnt + 2) * 2);\r | |
3100 | Update = FALSE;\r | |
3101 | }\r | |
3102 | }\r | |
3103 | \r | |
3104 | if ((!Short && Index != 16) || (*Ip6Str != '\0')) {\r | |
3105 | return EFI_INVALID_PARAMETER;\r | |
3106 | }\r | |
3107 | \r | |
3108 | return EFI_SUCCESS;\r | |
3109 | }\r | |
3110 | \r | |
3111 | \r | |
3112 | /**\r | |
3113 | Convert one Null-terminated Unicode string (decimal dotted) to EFI_IPv4_ADDRESS.\r | |
3114 | \r | |
3115 | @param[in] String The pointer to the Ascii string.\r | |
3116 | @param[out] Ip4Address The pointer to the converted IPv4 address.\r | |
3117 | \r | |
dd29f3ed | 3118 | @retval EFI_SUCCESS Convert to IPv4 address successfully.\r |
e4ef0031 | 3119 | @retval EFI_INVALID_PARAMETER The string is mal-formated or Ip4Address is NULL.\r |
3120 | @retval EFI_OUT_OF_RESOURCES Fail to perform the operation due to lack of resource.\r | |
3121 | \r | |
3122 | **/\r | |
3123 | EFI_STATUS\r | |
e798cd87 | 3124 | EFIAPI\r |
e4ef0031 | 3125 | NetLibStrToIp4 (\r |
3126 | IN CONST CHAR16 *String,\r | |
3127 | OUT EFI_IPv4_ADDRESS *Ip4Address\r | |
3128 | )\r | |
3129 | {\r | |
3130 | CHAR8 *Ip4Str;\r | |
3131 | EFI_STATUS Status;\r | |
dd29f3ed | 3132 | \r |
e4ef0031 | 3133 | if ((String == NULL) || (Ip4Address == NULL)) {\r |
3134 | return EFI_INVALID_PARAMETER;\r | |
3135 | }\r | |
3136 | \r | |
3137 | Ip4Str = (CHAR8 *) AllocatePool ((StrLen (String) + 1) * sizeof (CHAR8));\r | |
3138 | if (Ip4Str == NULL) {\r | |
3139 | return EFI_OUT_OF_RESOURCES;\r | |
3140 | }\r | |
3141 | \r | |
3142 | UnicodeStrToAsciiStr (String, Ip4Str);\r | |
3143 | \r | |
3144 | Status = NetLibAsciiStrToIp4 (Ip4Str, Ip4Address);\r | |
3145 | \r | |
3146 | FreePool (Ip4Str);\r | |
3147 | \r | |
3148 | return Status;\r | |
3149 | }\r | |
3150 | \r | |
3151 | \r | |
3152 | /**\r | |
3153 | Convert one Null-terminated Unicode string to EFI_IPv6_ADDRESS. The format of\r | |
3154 | the string is defined in RFC 4291 - Text Pepresentation of Addresses.\r | |
3155 | \r | |
3156 | @param[in] String The pointer to the Ascii string.\r | |
3157 | @param[out] Ip6Address The pointer to the converted IPv6 address.\r | |
3158 | \r | |
dd29f3ed | 3159 | @retval EFI_SUCCESS Convert to IPv6 address successfully.\r |
e4ef0031 | 3160 | @retval EFI_INVALID_PARAMETER The string is mal-formated or Ip6Address is NULL.\r |
3161 | @retval EFI_OUT_OF_RESOURCES Fail to perform the operation due to lack of resource.\r | |
3162 | \r | |
3163 | **/\r | |
3164 | EFI_STATUS\r | |
e798cd87 | 3165 | EFIAPI\r |
e4ef0031 | 3166 | NetLibStrToIp6 (\r |
3167 | IN CONST CHAR16 *String,\r | |
3168 | OUT EFI_IPv6_ADDRESS *Ip6Address\r | |
dd29f3ed | 3169 | )\r |
e4ef0031 | 3170 | {\r |
3171 | CHAR8 *Ip6Str;\r | |
3172 | EFI_STATUS Status;\r | |
dd29f3ed | 3173 | \r |
e4ef0031 | 3174 | if ((String == NULL) || (Ip6Address == NULL)) {\r |
3175 | return EFI_INVALID_PARAMETER;\r | |
3176 | }\r | |
3177 | \r | |
3178 | Ip6Str = (CHAR8 *) AllocatePool ((StrLen (String) + 1) * sizeof (CHAR8));\r | |
3179 | if (Ip6Str == NULL) {\r | |
3180 | return EFI_OUT_OF_RESOURCES;\r | |
3181 | }\r | |
3182 | \r | |
3183 | UnicodeStrToAsciiStr (String, Ip6Str);\r | |
3184 | \r | |
3185 | Status = NetLibAsciiStrToIp6 (Ip6Str, Ip6Address);\r | |
3186 | \r | |
3187 | FreePool (Ip6Str);\r | |
3188 | \r | |
3189 | return Status;\r | |
3190 | }\r | |
3191 | \r | |
3192 | /**\r | |
3193 | Convert one Null-terminated Unicode string to EFI_IPv6_ADDRESS and prefix length.\r | |
3194 | The format of the string is defined in RFC 4291 - Text Pepresentation of Addresses\r | |
3195 | Prefixes: ipv6-address/prefix-length.\r | |
3196 | \r | |
3197 | @param[in] String The pointer to the Ascii string.\r | |
3198 | @param[out] Ip6Address The pointer to the converted IPv6 address.\r | |
3199 | @param[out] PrefixLength The pointer to the converted prefix length.\r | |
3200 | \r | |
dd29f3ed | 3201 | @retval EFI_SUCCESS Convert to IPv6 address successfully.\r |
e4ef0031 | 3202 | @retval EFI_INVALID_PARAMETER The string is mal-formated or Ip6Address is NULL.\r |
3203 | @retval EFI_OUT_OF_RESOURCES Fail to perform the operation due to lack of resource.\r | |
3204 | \r | |
3205 | **/\r | |
3206 | EFI_STATUS\r | |
e798cd87 | 3207 | EFIAPI\r |
e4ef0031 | 3208 | NetLibStrToIp6andPrefix (\r |
3209 | IN CONST CHAR16 *String,\r | |
3210 | OUT EFI_IPv6_ADDRESS *Ip6Address,\r | |
3211 | OUT UINT8 *PrefixLength\r | |
dd29f3ed | 3212 | )\r |
e4ef0031 | 3213 | {\r |
dd29f3ed | 3214 | CHAR8 *Ip6Str;\r |
e4ef0031 | 3215 | CHAR8 *PrefixStr;\r |
3216 | CHAR8 *TempStr;\r | |
3217 | EFI_STATUS Status;\r | |
3218 | UINT8 Length;\r | |
dd29f3ed | 3219 | \r |
e4ef0031 | 3220 | if ((String == NULL) || (Ip6Address == NULL) || (PrefixLength == NULL)) {\r |
3221 | return EFI_INVALID_PARAMETER;\r | |
3222 | }\r | |
3223 | \r | |
3224 | Ip6Str = (CHAR8 *) AllocatePool ((StrLen (String) + 1) * sizeof (CHAR8));\r | |
3225 | if (Ip6Str == NULL) {\r | |
3226 | return EFI_OUT_OF_RESOURCES;\r | |
3227 | }\r | |
3228 | \r | |
3229 | UnicodeStrToAsciiStr (String, Ip6Str);\r | |
3230 | \r | |
3231 | //\r | |
3232 | // Get the sub string describing prefix length.\r | |
3233 | //\r | |
3234 | TempStr = Ip6Str;\r | |
3235 | while (*TempStr != '\0' && (*TempStr != '/')) {\r | |
3236 | TempStr++;\r | |
3237 | }\r | |
3238 | \r | |
3239 | if (*TempStr == '/') {\r | |
3240 | PrefixStr = TempStr + 1;\r | |
3241 | } else {\r | |
3242 | PrefixStr = NULL;\r | |
3243 | }\r | |
3244 | \r | |
3245 | //\r | |
3246 | // Get the sub string describing IPv6 address and convert it.\r | |
3247 | //\r | |
3248 | *TempStr = '\0';\r | |
3249 | \r | |
3250 | Status = NetLibAsciiStrToIp6 (Ip6Str, Ip6Address);\r | |
3251 | if (EFI_ERROR (Status)) {\r | |
3252 | goto Exit;\r | |
3253 | }\r | |
3254 | \r | |
04bb6788 | 3255 | //\r |
3256 | // If input string doesn't indicate the prefix length, return 0xff.\r | |
3257 | //\r | |
3258 | Length = 0xFF;\r | |
1dc1b43f | 3259 | \r |
e4ef0031 | 3260 | //\r |
3261 | // Convert the string to prefix length\r | |
3262 | //\r | |
e4ef0031 | 3263 | if (PrefixStr != NULL) {\r |
3264 | \r | |
3265 | Status = EFI_INVALID_PARAMETER;\r | |
04bb6788 | 3266 | Length = 0;\r |
e4ef0031 | 3267 | while (*PrefixStr != '\0') {\r |
3268 | if (NET_IS_DIGIT (*PrefixStr)) {\r | |
3269 | Length = (UINT8) (Length * 10 + (*PrefixStr - '0'));\r | |
3270 | if (Length >= IP6_PREFIX_NUM) {\r | |
3271 | goto Exit;\r | |
3272 | }\r | |
3273 | } else {\r | |
3274 | goto Exit;\r | |
3275 | }\r | |
3276 | \r | |
3277 | PrefixStr++;\r | |
3278 | }\r | |
3279 | }\r | |
3280 | \r | |
3281 | *PrefixLength = Length;\r | |
3282 | Status = EFI_SUCCESS;\r | |
3283 | \r | |
3284 | Exit:\r | |
3285 | \r | |
3286 | FreePool (Ip6Str);\r | |
3287 | return Status;\r | |
3288 | }\r | |
3289 | \r | |
216f7970 | 3290 | /**\r |
3291 | \r | |
3292 | Convert one EFI_IPv6_ADDRESS to Null-terminated Unicode string.\r | |
3293 | The text representation of address is defined in RFC 4291.\r | |
3294 | \r | |
3295 | @param[in] Ip6Address The pointer to the IPv6 address.\r | |
3296 | @param[out] String The buffer to return the converted string.\r | |
3297 | @param[in] StringSize The length in bytes of the input String.\r | |
3298 | \r | |
3299 | @retval EFI_SUCCESS Convert to string successfully.\r | |
3300 | @retval EFI_INVALID_PARAMETER The input parameter is invalid.\r | |
3301 | @retval EFI_BUFFER_TOO_SMALL The BufferSize is too small for the result. BufferSize has been \r | |
3302 | updated with the size needed to complete the request.\r | |
3303 | **/\r | |
3304 | EFI_STATUS\r | |
3305 | EFIAPI\r | |
3306 | NetLibIp6ToStr (\r | |
3307 | IN EFI_IPv6_ADDRESS *Ip6Address,\r | |
3308 | OUT CHAR16 *String,\r | |
3309 | IN UINTN StringSize\r | |
3310 | )\r | |
3311 | {\r | |
3312 | UINT16 Ip6Addr[8];\r | |
3313 | UINTN Index;\r | |
3314 | UINTN LongestZerosStart;\r | |
3315 | UINTN LongestZerosLength;\r | |
3316 | UINTN CurrentZerosStart;\r | |
3317 | UINTN CurrentZerosLength;\r | |
3318 | CHAR16 Buffer[sizeof"ffff:ffff:ffff:ffff:ffff:ffff:ffff:ffff"];\r | |
3319 | CHAR16 *Ptr;\r | |
3320 | \r | |
3321 | if (Ip6Address == NULL || String == NULL || StringSize == 0) {\r | |
3322 | return EFI_INVALID_PARAMETER;\r | |
3323 | }\r | |
3324 | \r | |
3325 | //\r | |
3326 | // Convert the UINT8 array to an UINT16 array for easy handling.\r | |
3327 | // \r | |
3328 | ZeroMem (Ip6Addr, sizeof (Ip6Addr));\r | |
3329 | for (Index = 0; Index < 16; Index++) {\r | |
3330 | Ip6Addr[Index / 2] |= (Ip6Address->Addr[Index] << ((1 - (Index % 2)) << 3));\r | |
3331 | }\r | |
57b301b5 | 3332 | \r |
216f7970 | 3333 | //\r |
3334 | // Find the longest zeros and mark it.\r | |
3335 | //\r | |
3336 | CurrentZerosStart = DEFAULT_ZERO_START;\r | |
3337 | CurrentZerosLength = 0;\r | |
3338 | LongestZerosStart = DEFAULT_ZERO_START;\r | |
3339 | LongestZerosLength = 0;\r | |
3340 | for (Index = 0; Index < 8; Index++) {\r | |
3341 | if (Ip6Addr[Index] == 0) {\r | |
3342 | if (CurrentZerosStart == DEFAULT_ZERO_START) {\r | |
3343 | CurrentZerosStart = Index;\r | |
3344 | CurrentZerosLength = 1;\r | |
3345 | } else {\r | |
3346 | CurrentZerosLength++;\r | |
3347 | }\r | |
3348 | } else {\r | |
3349 | if (CurrentZerosStart != DEFAULT_ZERO_START) {\r | |
3350 | if (CurrentZerosLength > 2 && (LongestZerosStart == (DEFAULT_ZERO_START) || CurrentZerosLength > LongestZerosLength)) {\r | |
3351 | LongestZerosStart = CurrentZerosStart;\r | |
3352 | LongestZerosLength = CurrentZerosLength;\r | |
3353 | }\r | |
3354 | CurrentZerosStart = DEFAULT_ZERO_START;\r | |
3355 | CurrentZerosLength = 0;\r | |
3356 | }\r | |
3357 | }\r | |
3358 | }\r | |
3359 | \r | |
3360 | if (CurrentZerosStart != DEFAULT_ZERO_START && CurrentZerosLength > 2) {\r | |
3361 | if (LongestZerosStart == DEFAULT_ZERO_START || LongestZerosLength < CurrentZerosLength) {\r | |
3362 | LongestZerosStart = CurrentZerosStart;\r | |
3363 | LongestZerosLength = CurrentZerosLength;\r | |
3364 | }\r | |
3365 | }\r | |
3366 | \r | |
3367 | Ptr = Buffer;\r | |
3368 | for (Index = 0; Index < 8; Index++) {\r | |
3369 | if (LongestZerosStart != DEFAULT_ZERO_START && Index >= LongestZerosStart && Index < LongestZerosStart + LongestZerosLength) {\r | |
3370 | if (Index == LongestZerosStart) {\r | |
3371 | *Ptr++ = L':';\r | |
3372 | }\r | |
3373 | continue;\r | |
3374 | }\r | |
3375 | if (Index != 0) {\r | |
3376 | *Ptr++ = L':';\r | |
3377 | }\r | |
3378 | Ptr += UnicodeSPrint(Ptr, 10, L"%x", Ip6Addr[Index]);\r | |
3379 | }\r | |
3380 | \r | |
3381 | if (LongestZerosStart != DEFAULT_ZERO_START && LongestZerosStart + LongestZerosLength == 8) {\r | |
3382 | *Ptr++ = L':';\r | |
3383 | }\r | |
3384 | *Ptr = L'\0';\r | |
3385 | \r | |
3386 | if ((UINTN)Ptr - (UINTN)Buffer > StringSize) {\r | |
3387 | return EFI_BUFFER_TOO_SMALL;\r | |
3388 | }\r | |
3389 | \r | |
3390 | StrCpy (String, Buffer);\r | |
3391 | \r | |
3392 | return EFI_SUCCESS;\r | |
3393 | }\r | |
57b301b5 | 3394 | \r |
3395 | /**\r | |
3396 | This function obtains the system guid from the smbios table.\r | |
3397 | \r | |
3398 | @param[out] SystemGuid The pointer of the returned system guid.\r | |
3399 | \r | |
3400 | @retval EFI_SUCCESS Successfully obtained the system guid.\r | |
3401 | @retval EFI_NOT_FOUND Did not find the SMBIOS table.\r | |
3402 | \r | |
3403 | **/\r | |
3404 | EFI_STATUS\r | |
3405 | EFIAPI\r | |
3406 | NetLibGetSystemGuid (\r | |
3407 | OUT EFI_GUID *SystemGuid\r | |
3408 | )\r | |
3409 | {\r | |
3410 | EFI_STATUS Status;\r | |
3411 | SMBIOS_TABLE_ENTRY_POINT *SmbiosTable;\r | |
3412 | SMBIOS_STRUCTURE_POINTER Smbios;\r | |
3413 | SMBIOS_STRUCTURE_POINTER SmbiosEnd;\r | |
3414 | CHAR8 *String;\r | |
3415 | \r | |
3416 | SmbiosTable = NULL;\r | |
3417 | Status = EfiGetSystemConfigurationTable (&gEfiSmbiosTableGuid, (VOID **) &SmbiosTable);\r | |
3418 | \r | |
3419 | if (EFI_ERROR (Status) || SmbiosTable == NULL) {\r | |
3420 | return EFI_NOT_FOUND;\r | |
3421 | }\r | |
3422 | \r | |
3423 | Smbios.Hdr = (SMBIOS_STRUCTURE *) (UINTN) SmbiosTable->TableAddress;\r | |
3424 | SmbiosEnd.Raw = (UINT8 *) (UINTN) (SmbiosTable->TableAddress + SmbiosTable->TableLength);\r | |
3425 | \r | |
3426 | do {\r | |
3427 | if (Smbios.Hdr->Type == 1) {\r | |
3428 | if (Smbios.Hdr->Length < 0x19) {\r | |
3429 | //\r | |
3430 | // Older version did not support UUID.\r | |
3431 | //\r | |
3432 | return EFI_NOT_FOUND;\r | |
3433 | }\r | |
3434 | \r | |
3435 | //\r | |
3436 | // SMBIOS tables are byte packed so we need to do a byte copy to\r | |
3437 | // prevend alignment faults on Itanium-based platform.\r | |
3438 | //\r | |
3439 | CopyMem (SystemGuid, &Smbios.Type1->Uuid, sizeof (EFI_GUID));\r | |
3440 | return EFI_SUCCESS;\r | |
3441 | }\r | |
3442 | \r | |
3443 | //\r | |
3444 | // Go to the next SMBIOS structure. Each SMBIOS structure may include 2 parts:\r | |
3445 | // 1. Formatted section; 2. Unformatted string section. So, 2 steps are needed\r | |
3446 | // to skip one SMBIOS structure.\r | |
3447 | //\r | |
3448 | \r | |
3449 | //\r | |
3450 | // Step 1: Skip over formatted section.\r | |
3451 | //\r | |
3452 | String = (CHAR8 *) (Smbios.Raw + Smbios.Hdr->Length);\r | |
3453 | \r | |
3454 | //\r | |
3455 | // Step 2: Skip over unformated string section.\r | |
3456 | //\r | |
3457 | do {\r | |
3458 | //\r | |
3459 | // Each string is terminated with a NULL(00h) BYTE and the sets of strings\r | |
3460 | // is terminated with an additional NULL(00h) BYTE.\r | |
3461 | //\r | |
3462 | for ( ; *String != 0; String++) {\r | |
3463 | }\r | |
3464 | \r | |
3465 | if (*(UINT8*)++String == 0) {\r | |
3466 | //\r | |
3467 | // Pointer to the next SMBIOS structure.\r | |
3468 | //\r | |
3469 | Smbios.Raw = (UINT8 *)++String;\r | |
3470 | break;\r | |
3471 | } \r | |
3472 | } while (TRUE);\r | |
3473 | } while (Smbios.Raw < SmbiosEnd.Raw);\r | |
3474 | return EFI_NOT_FOUND;\r | |
3475 | }\r |