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CryptoPkg: Extend Tls function library
[mirror_edk2.git] / CryptoPkg / Library / TlsLib / TlsConfig.c
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1/** @file\r
2 SSL/TLS Configuration Library Wrapper Implementation over OpenSSL.\r
3\r
4Copyright (c) 2016 - 2018, Intel Corporation. All rights reserved.<BR>\r
5(C) Copyright 2016 Hewlett Packard Enterprise Development LP<BR>\r
6SPDX-License-Identifier: BSD-2-Clause-Patent\r
7\r
8**/\r
9\r
10#include "InternalTlsLib.h"\r
11\r
12typedef struct {\r
13 //\r
14 // IANA/IETF defined Cipher Suite ID\r
15 //\r
16 UINT16 IanaCipher;\r
17 //\r
18 // OpenSSL-used Cipher Suite String\r
19 //\r
20 CONST CHAR8 *OpensslCipher;\r
21 //\r
22 // Length of OpensslCipher\r
23 //\r
24 UINTN OpensslCipherLength;\r
25} TLS_CIPHER_MAPPING;\r
26\r
27//\r
28// Create a TLS_CIPHER_MAPPING initializer from IanaCipher and OpensslCipher so\r
29// that OpensslCipherLength is filled in automatically. IanaCipher must be an\r
30// integer constant expression, and OpensslCipher must be a string literal.\r
31//\r
32#define MAP(IanaCipher, OpensslCipher) \\r
33 { (IanaCipher), (OpensslCipher), sizeof (OpensslCipher) - 1 }\r
34\r
35//\r
36// The mapping table between IANA/IETF Cipher Suite definitions and\r
37// OpenSSL-used Cipher Suite name.\r
38//\r
39// Keep the table uniquely sorted by the IanaCipher field, in increasing order.\r
40//\r
41STATIC CONST TLS_CIPHER_MAPPING TlsCipherMappingTable[] = {\r
42 MAP (0x0001, "NULL-MD5"), /// TLS_RSA_WITH_NULL_MD5\r
43 MAP (0x0002, "NULL-SHA"), /// TLS_RSA_WITH_NULL_SHA\r
44 MAP (0x0004, "RC4-MD5"), /// TLS_RSA_WITH_RC4_128_MD5\r
45 MAP (0x0005, "RC4-SHA"), /// TLS_RSA_WITH_RC4_128_SHA\r
46 MAP (0x000A, "DES-CBC3-SHA"), /// TLS_RSA_WITH_3DES_EDE_CBC_SHA, mandatory TLS 1.1\r
47 MAP (0x0016, "DHE-RSA-DES-CBC3-SHA"), /// TLS_DHE_RSA_WITH_3DES_EDE_CBC_SHA\r
48 MAP (0x002F, "AES128-SHA"), /// TLS_RSA_WITH_AES_128_CBC_SHA, mandatory TLS 1.2\r
49 MAP (0x0030, "DH-DSS-AES128-SHA"), /// TLS_DH_DSS_WITH_AES_128_CBC_SHA\r
50 MAP (0x0031, "DH-RSA-AES128-SHA"), /// TLS_DH_RSA_WITH_AES_128_CBC_SHA\r
51 MAP (0x0033, "DHE-RSA-AES128-SHA"), /// TLS_DHE_RSA_WITH_AES_128_CBC_SHA\r
52 MAP (0x0035, "AES256-SHA"), /// TLS_RSA_WITH_AES_256_CBC_SHA\r
53 MAP (0x0036, "DH-DSS-AES256-SHA"), /// TLS_DH_DSS_WITH_AES_256_CBC_SHA\r
54 MAP (0x0037, "DH-RSA-AES256-SHA"), /// TLS_DH_RSA_WITH_AES_256_CBC_SHA\r
55 MAP (0x0039, "DHE-RSA-AES256-SHA"), /// TLS_DHE_RSA_WITH_AES_256_CBC_SHA\r
56 MAP (0x003B, "NULL-SHA256"), /// TLS_RSA_WITH_NULL_SHA256\r
57 MAP (0x003C, "AES128-SHA256"), /// TLS_RSA_WITH_AES_128_CBC_SHA256\r
58 MAP (0x003D, "AES256-SHA256"), /// TLS_RSA_WITH_AES_256_CBC_SHA256\r
59 MAP (0x003E, "DH-DSS-AES128-SHA256"), /// TLS_DH_DSS_WITH_AES_128_CBC_SHA256\r
60 MAP (0x003F, "DH-RSA-AES128-SHA256"), /// TLS_DH_RSA_WITH_AES_128_CBC_SHA256\r
61 MAP (0x0067, "DHE-RSA-AES128-SHA256"), /// TLS_DHE_RSA_WITH_AES_128_CBC_SHA256\r
62 MAP (0x0068, "DH-DSS-AES256-SHA256"), /// TLS_DH_DSS_WITH_AES_256_CBC_SHA256\r
63 MAP (0x0069, "DH-RSA-AES256-SHA256"), /// TLS_DH_RSA_WITH_AES_256_CBC_SHA256\r
64 MAP (0x006B, "DHE-RSA-AES256-SHA256"), /// TLS_DHE_RSA_WITH_AES_256_CBC_SHA256\r
65 MAP (0x009F, "DHE-RSA-AES256-GCM-SHA384"), /// TLS_DHE_RSA_WITH_AES_256_GCM_SHA384\r
66 MAP (0xC02B, "ECDHE-ECDSA-AES128-GCM-SHA256"), /// TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256\r
67 MAP (0xC02C, "ECDHE-ECDSA-AES256-GCM-SHA384"), /// TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384\r
68 MAP (0xC030, "ECDHE-RSA-AES256-GCM-SHA384"), /// TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384\r
69};\r
70\r
71typedef struct {\r
72 //\r
73 // TLS Algorithm\r
74 //\r
75 UINT8 Algo;\r
76 //\r
77 // TLS Algorithm name\r
78 //\r
79 CONST CHAR8 *Name;\r
80} TLS_ALGO_TO_NAME;\r
81\r
82STATIC CONST TLS_ALGO_TO_NAME TlsHashAlgoToName[] = {\r
83 { TlsHashAlgoNone, NULL },\r
84 { TlsHashAlgoMd5, "MD5" },\r
85 { TlsHashAlgoSha1, "SHA1" },\r
86 { TlsHashAlgoSha224, "SHA224" },\r
87 { TlsHashAlgoSha256, "SHA256" },\r
88 { TlsHashAlgoSha384, "SHA384" },\r
89 { TlsHashAlgoSha512, "SHA512" },\r
90};\r
91\r
92STATIC CONST TLS_ALGO_TO_NAME TlsSignatureAlgoToName[] = {\r
93 { TlsSignatureAlgoAnonymous, NULL },\r
94 { TlsSignatureAlgoRsa, "RSA" },\r
95 { TlsSignatureAlgoDsa, "DSA" },\r
96 { TlsSignatureAlgoEcdsa, "ECDSA" },\r
97};\r
98\r
99/**\r
100 Gets the OpenSSL cipher suite mapping for the supplied IANA TLS cipher suite.\r
101\r
102 @param[in] CipherId The supplied IANA TLS cipher suite ID.\r
103\r
104 @return The corresponding OpenSSL cipher suite mapping if found,\r
105 NULL otherwise.\r
106\r
107**/\r
108STATIC\r
109CONST TLS_CIPHER_MAPPING *\r
110TlsGetCipherMapping (\r
111 IN UINT16 CipherId\r
112 )\r
113{\r
114 INTN Left;\r
115 INTN Right;\r
116 INTN Middle;\r
117\r
118 //\r
119 // Binary Search Cipher Mapping Table for IANA-OpenSSL Cipher Translation\r
120 //\r
121 Left = 0;\r
122 Right = ARRAY_SIZE (TlsCipherMappingTable) - 1;\r
123\r
124 while (Right >= Left) {\r
125 Middle = (Left + Right) / 2;\r
126\r
127 if (CipherId == TlsCipherMappingTable[Middle].IanaCipher) {\r
128 //\r
129 // Translate IANA cipher suite ID to OpenSSL name.\r
130 //\r
131 return &TlsCipherMappingTable[Middle];\r
132 }\r
133\r
134 if (CipherId < TlsCipherMappingTable[Middle].IanaCipher) {\r
135 Right = Middle - 1;\r
136 } else {\r
137 Left = Middle + 1;\r
138 }\r
139 }\r
140\r
141 //\r
142 // No Cipher Mapping found, return NULL.\r
143 //\r
144 return NULL;\r
145}\r
146\r
147/**\r
148 Set a new TLS/SSL method for a particular TLS object.\r
149\r
150 This function sets a new TLS/SSL method for a particular TLS object.\r
151\r
152 @param[in] Tls Pointer to a TLS object.\r
153 @param[in] MajorVer Major Version of TLS/SSL Protocol.\r
154 @param[in] MinorVer Minor Version of TLS/SSL Protocol.\r
155\r
156 @retval EFI_SUCCESS The TLS/SSL method was set successfully.\r
157 @retval EFI_INVALID_PARAMETER The parameter is invalid.\r
158 @retval EFI_UNSUPPORTED Unsupported TLS/SSL method.\r
159\r
160**/\r
161EFI_STATUS\r
162EFIAPI\r
163TlsSetVersion (\r
164 IN VOID *Tls,\r
165 IN UINT8 MajorVer,\r
166 IN UINT8 MinorVer\r
167 )\r
168{\r
169 TLS_CONNECTION *TlsConn;\r
170 UINT16 ProtoVersion;\r
171\r
172 TlsConn = (TLS_CONNECTION *)Tls;\r
173 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL)) {\r
174 return EFI_INVALID_PARAMETER;\r
175 }\r
176\r
177 ProtoVersion = (MajorVer << 8) | MinorVer;\r
178\r
179 //\r
180 // Bound TLS method to the particular specified version.\r
181 //\r
182 switch (ProtoVersion) {\r
183 case TLS1_VERSION:\r
184 //\r
185 // TLS 1.0\r
186 //\r
187 SSL_set_min_proto_version (TlsConn->Ssl, TLS1_VERSION);\r
188 SSL_set_max_proto_version (TlsConn->Ssl, TLS1_VERSION);\r
189 break;\r
190 case TLS1_1_VERSION:\r
191 //\r
192 // TLS 1.1\r
193 //\r
194 SSL_set_min_proto_version (TlsConn->Ssl, TLS1_1_VERSION);\r
195 SSL_set_max_proto_version (TlsConn->Ssl, TLS1_1_VERSION);\r
196 break;\r
197 case TLS1_2_VERSION:\r
198 //\r
199 // TLS 1.2\r
200 //\r
201 SSL_set_min_proto_version (TlsConn->Ssl, TLS1_2_VERSION);\r
202 SSL_set_max_proto_version (TlsConn->Ssl, TLS1_2_VERSION);\r
203 break;\r
204 default:\r
205 //\r
206 // Unsupported Protocol Version\r
207 //\r
208 return EFI_UNSUPPORTED;\r
209 }\r
210\r
211 return EFI_SUCCESS;\r
212}\r
213\r
214/**\r
215 Set TLS object to work in client or server mode.\r
216\r
217 This function prepares a TLS object to work in client or server mode.\r
218\r
219 @param[in] Tls Pointer to a TLS object.\r
220 @param[in] IsServer Work in server mode.\r
221\r
222 @retval EFI_SUCCESS The TLS/SSL work mode was set successfully.\r
223 @retval EFI_INVALID_PARAMETER The parameter is invalid.\r
224 @retval EFI_UNSUPPORTED Unsupported TLS/SSL work mode.\r
225\r
226**/\r
227EFI_STATUS\r
228EFIAPI\r
229TlsSetConnectionEnd (\r
230 IN VOID *Tls,\r
231 IN BOOLEAN IsServer\r
232 )\r
233{\r
234 TLS_CONNECTION *TlsConn;\r
235\r
236 TlsConn = (TLS_CONNECTION *)Tls;\r
237 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL)) {\r
238 return EFI_INVALID_PARAMETER;\r
239 }\r
240\r
241 if (!IsServer) {\r
242 //\r
243 // Set TLS to work in Client mode.\r
244 //\r
245 SSL_set_connect_state (TlsConn->Ssl);\r
246 } else {\r
247 //\r
248 // Set TLS to work in Server mode.\r
249 // It is unsupported for UEFI version currently.\r
250 //\r
251 // SSL_set_accept_state (TlsConn->Ssl);\r
252 return EFI_UNSUPPORTED;\r
253 }\r
254\r
255 return EFI_SUCCESS;\r
256}\r
257\r
258/**\r
259 Set the ciphers list to be used by the TLS object.\r
260\r
261 This function sets the ciphers for use by a specified TLS object.\r
262\r
263 @param[in] Tls Pointer to a TLS object.\r
264 @param[in] CipherId Array of UINT16 cipher identifiers. Each UINT16\r
265 cipher identifier comes from the TLS Cipher Suite\r
266 Registry of the IANA, interpreting Byte1 and Byte2\r
267 in network (big endian) byte order.\r
268 @param[in] CipherNum The number of cipher in the list.\r
269\r
270 @retval EFI_SUCCESS The ciphers list was set successfully.\r
271 @retval EFI_INVALID_PARAMETER The parameter is invalid.\r
272 @retval EFI_UNSUPPORTED No supported TLS cipher was found in CipherId.\r
273 @retval EFI_OUT_OF_RESOURCES Memory allocation failed.\r
274\r
275**/\r
276EFI_STATUS\r
277EFIAPI\r
278TlsSetCipherList (\r
279 IN VOID *Tls,\r
280 IN UINT16 *CipherId,\r
281 IN UINTN CipherNum\r
282 )\r
283{\r
284 TLS_CONNECTION *TlsConn;\r
285 EFI_STATUS Status;\r
286 CONST TLS_CIPHER_MAPPING **MappedCipher;\r
287 UINTN MappedCipherBytes;\r
288 UINTN MappedCipherCount;\r
289 UINTN CipherStringSize;\r
290 UINTN Index;\r
291 CONST TLS_CIPHER_MAPPING *Mapping;\r
292 CHAR8 *CipherString;\r
293 CHAR8 *CipherStringPosition;\r
294\r
295 TlsConn = (TLS_CONNECTION *)Tls;\r
296 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL) || (CipherId == NULL)) {\r
297 return EFI_INVALID_PARAMETER;\r
298 }\r
299\r
300 //\r
301 // Allocate the MappedCipher array for recording the mappings that we find\r
302 // for the input IANA identifiers in CipherId.\r
303 //\r
304 Status = SafeUintnMult (\r
305 CipherNum,\r
306 sizeof (*MappedCipher),\r
307 &MappedCipherBytes\r
308 );\r
309 if (EFI_ERROR (Status)) {\r
310 return EFI_OUT_OF_RESOURCES;\r
311 }\r
312\r
313 MappedCipher = AllocatePool (MappedCipherBytes);\r
314 if (MappedCipher == NULL) {\r
315 return EFI_OUT_OF_RESOURCES;\r
316 }\r
317\r
318 //\r
319 // Map the cipher IDs, and count the number of bytes for the full\r
320 // CipherString.\r
321 //\r
322 MappedCipherCount = 0;\r
323 CipherStringSize = 0;\r
324 for (Index = 0; Index < CipherNum; Index++) {\r
325 //\r
326 // Look up the IANA-to-OpenSSL mapping.\r
327 //\r
328 Mapping = TlsGetCipherMapping (CipherId[Index]);\r
329 if (Mapping == NULL) {\r
330 DEBUG ((\r
331 DEBUG_VERBOSE,\r
332 "%a:%a: skipping CipherId=0x%04x\n",\r
333 gEfiCallerBaseName,\r
334 __FUNCTION__,\r
335 CipherId[Index]\r
336 ));\r
337 //\r
338 // Skipping the cipher is valid because CipherId is an ordered\r
339 // preference list of ciphers, thus we can filter it as long as we\r
340 // don't change the relative order of elements on it.\r
341 //\r
342 continue;\r
343 }\r
344\r
345 //\r
346 // Accumulate Mapping->OpensslCipherLength into CipherStringSize. If this\r
347 // is not the first successful mapping, account for a colon (":") prefix\r
348 // too.\r
349 //\r
350 if (MappedCipherCount > 0) {\r
351 Status = SafeUintnAdd (CipherStringSize, 1, &CipherStringSize);\r
352 if (EFI_ERROR (Status)) {\r
353 Status = EFI_OUT_OF_RESOURCES;\r
354 goto FreeMappedCipher;\r
355 }\r
356 }\r
357\r
358 Status = SafeUintnAdd (\r
359 CipherStringSize,\r
360 Mapping->OpensslCipherLength,\r
361 &CipherStringSize\r
362 );\r
363 if (EFI_ERROR (Status)) {\r
364 Status = EFI_OUT_OF_RESOURCES;\r
365 goto FreeMappedCipher;\r
366 }\r
367\r
368 //\r
369 // Record the mapping.\r
370 //\r
371 MappedCipher[MappedCipherCount++] = Mapping;\r
372 }\r
373\r
374 //\r
375 // Verify that at least one IANA cipher ID could be mapped; account for the\r
376 // terminating NUL character in CipherStringSize; allocate CipherString.\r
377 //\r
378 if (MappedCipherCount == 0) {\r
379 DEBUG ((\r
380 DEBUG_ERROR,\r
381 "%a:%a: no CipherId could be mapped\n",\r
382 gEfiCallerBaseName,\r
383 __FUNCTION__\r
384 ));\r
385 Status = EFI_UNSUPPORTED;\r
386 goto FreeMappedCipher;\r
387 }\r
388\r
389 Status = SafeUintnAdd (CipherStringSize, 1, &CipherStringSize);\r
390 if (EFI_ERROR (Status)) {\r
391 Status = EFI_OUT_OF_RESOURCES;\r
392 goto FreeMappedCipher;\r
393 }\r
394\r
395 CipherString = AllocatePool (CipherStringSize);\r
396 if (CipherString == NULL) {\r
397 Status = EFI_OUT_OF_RESOURCES;\r
398 goto FreeMappedCipher;\r
399 }\r
400\r
401 //\r
402 // Go over the collected mappings and populate CipherString.\r
403 //\r
404 CipherStringPosition = CipherString;\r
405 for (Index = 0; Index < MappedCipherCount; Index++) {\r
406 Mapping = MappedCipher[Index];\r
407 //\r
408 // Append the colon (":") prefix except for the first mapping, then append\r
409 // Mapping->OpensslCipher.\r
410 //\r
411 if (Index > 0) {\r
412 *(CipherStringPosition++) = ':';\r
413 }\r
414\r
415 CopyMem (\r
416 CipherStringPosition,\r
417 Mapping->OpensslCipher,\r
418 Mapping->OpensslCipherLength\r
419 );\r
420 CipherStringPosition += Mapping->OpensslCipherLength;\r
421 }\r
422\r
423 //\r
424 // NUL-terminate CipherString.\r
425 //\r
426 *(CipherStringPosition++) = '\0';\r
427 ASSERT (CipherStringPosition == CipherString + CipherStringSize);\r
428\r
429 //\r
430 // Log CipherString for debugging. CipherString can be very long if the\r
431 // caller provided a large CipherId array, so log CipherString in segments of\r
432 // 79 non-newline characters. (MAX_DEBUG_MESSAGE_LENGTH is usually 0x100 in\r
433 // DebugLib instances.)\r
434 //\r
435 DEBUG_CODE_BEGIN ();\r
436 UINTN FullLength;\r
437 UINTN SegmentLength;\r
438\r
439 FullLength = CipherStringSize - 1;\r
440 DEBUG ((\r
441 DEBUG_VERBOSE,\r
442 "%a:%a: CipherString={\n",\r
443 gEfiCallerBaseName,\r
444 __FUNCTION__\r
445 ));\r
446 for (CipherStringPosition = CipherString;\r
447 CipherStringPosition < CipherString + FullLength;\r
448 CipherStringPosition += SegmentLength)\r
449 {\r
450 SegmentLength = FullLength - (CipherStringPosition - CipherString);\r
451 if (SegmentLength > 79) {\r
452 SegmentLength = 79;\r
453 }\r
454\r
455 DEBUG ((DEBUG_VERBOSE, "%.*a\n", SegmentLength, CipherStringPosition));\r
456 }\r
457\r
458 DEBUG ((DEBUG_VERBOSE, "}\n"));\r
459 //\r
460 // Restore the pre-debug value of CipherStringPosition by skipping over the\r
461 // trailing NUL.\r
462 //\r
463 CipherStringPosition++;\r
464 ASSERT (CipherStringPosition == CipherString + CipherStringSize);\r
465 DEBUG_CODE_END ();\r
466\r
467 //\r
468 // Sets the ciphers for use by the Tls object.\r
469 //\r
470 if (SSL_set_cipher_list (TlsConn->Ssl, CipherString) <= 0) {\r
471 Status = EFI_UNSUPPORTED;\r
472 goto FreeCipherString;\r
473 }\r
474\r
475 Status = EFI_SUCCESS;\r
476\r
477FreeCipherString:\r
478 FreePool (CipherString);\r
479\r
480FreeMappedCipher:\r
481 FreePool (MappedCipher);\r
482\r
483 return Status;\r
484}\r
485\r
486/**\r
487 Set the compression method for TLS/SSL operations.\r
488\r
489 This function handles TLS/SSL integrated compression methods.\r
490\r
491 @param[in] CompMethod The compression method ID.\r
492\r
493 @retval EFI_SUCCESS The compression method for the communication was\r
494 set successfully.\r
495 @retval EFI_UNSUPPORTED Unsupported compression method.\r
496\r
497**/\r
498EFI_STATUS\r
499EFIAPI\r
500TlsSetCompressionMethod (\r
501 IN UINT8 CompMethod\r
502 )\r
503{\r
504 COMP_METHOD *Cm;\r
505 INTN Ret;\r
506\r
507 Cm = NULL;\r
508 Ret = 0;\r
509\r
510 if (CompMethod == 0) {\r
511 //\r
512 // TLS defines one standard compression method, CompressionMethod.null (0),\r
513 // which specifies that data exchanged via the record protocol will not be compressed.\r
514 // So, return EFI_SUCCESS directly (RFC 3749).\r
515 //\r
516 return EFI_SUCCESS;\r
517 } else if (CompMethod == 1) {\r
518 Cm = COMP_zlib ();\r
519 } else {\r
520 return EFI_UNSUPPORTED;\r
521 }\r
522\r
523 //\r
524 // Adds the compression method to the list of available\r
525 // compression methods.\r
526 //\r
527 Ret = SSL_COMP_add_compression_method (CompMethod, Cm);\r
528 if (Ret != 0) {\r
529 return EFI_UNSUPPORTED;\r
530 }\r
531\r
532 return EFI_SUCCESS;\r
533}\r
534\r
535/**\r
536 Set peer certificate verification mode for the TLS connection.\r
537\r
538 This function sets the verification mode flags for the TLS connection.\r
539\r
540 @param[in] Tls Pointer to the TLS object.\r
541 @param[in] VerifyMode A set of logically or'ed verification mode flags.\r
542\r
543**/\r
544VOID\r
545EFIAPI\r
546TlsSetVerify (\r
547 IN VOID *Tls,\r
548 IN UINT32 VerifyMode\r
549 )\r
550{\r
551 TLS_CONNECTION *TlsConn;\r
552\r
553 TlsConn = (TLS_CONNECTION *)Tls;\r
554 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL)) {\r
555 return;\r
556 }\r
557\r
558 //\r
559 // Set peer certificate verification parameters with NULL callback.\r
560 //\r
561 SSL_set_verify (TlsConn->Ssl, VerifyMode, NULL);\r
562}\r
563\r
564/**\r
565 Set the specified host name to be verified.\r
566\r
567 @param[in] Tls Pointer to the TLS object.\r
568 @param[in] Flags The setting flags during the validation.\r
569 @param[in] HostName The specified host name to be verified.\r
570\r
571 @retval EFI_SUCCESS The HostName setting was set successfully.\r
572 @retval EFI_INVALID_PARAMETER The parameter is invalid.\r
573 @retval EFI_ABORTED Invalid HostName setting.\r
574\r
575**/\r
576EFI_STATUS\r
577EFIAPI\r
578TlsSetVerifyHost (\r
579 IN VOID *Tls,\r
580 IN UINT32 Flags,\r
581 IN CHAR8 *HostName\r
582 )\r
583{\r
584 TLS_CONNECTION *TlsConn;\r
585 X509_VERIFY_PARAM *VerifyParam;\r
586 UINTN BinaryAddressSize;\r
587 UINT8 BinaryAddress[MAX (NS_INADDRSZ, NS_IN6ADDRSZ)];\r
588 INTN ParamStatus;\r
589\r
590 TlsConn = (TLS_CONNECTION *)Tls;\r
591 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL) || (HostName == NULL)) {\r
592 return EFI_INVALID_PARAMETER;\r
593 }\r
594\r
595 SSL_set_hostflags (TlsConn->Ssl, Flags);\r
596\r
597 VerifyParam = SSL_get0_param (TlsConn->Ssl);\r
598 ASSERT (VerifyParam != NULL);\r
599\r
600 BinaryAddressSize = 0;\r
601 if (inet_pton (AF_INET6, HostName, BinaryAddress) == 1) {\r
602 BinaryAddressSize = NS_IN6ADDRSZ;\r
603 } else if (inet_pton (AF_INET, HostName, BinaryAddress) == 1) {\r
604 BinaryAddressSize = NS_INADDRSZ;\r
605 }\r
606\r
607 if (BinaryAddressSize > 0) {\r
608 DEBUG ((\r
609 DEBUG_VERBOSE,\r
610 "%a:%a: parsed \"%a\" as an IPv%c address "\r
611 "literal\n",\r
612 gEfiCallerBaseName,\r
613 __FUNCTION__,\r
614 HostName,\r
615 (UINTN)((BinaryAddressSize == NS_IN6ADDRSZ) ? '6' : '4')\r
616 ));\r
617 ParamStatus = X509_VERIFY_PARAM_set1_ip (\r
618 VerifyParam,\r
619 BinaryAddress,\r
620 BinaryAddressSize\r
621 );\r
622 } else {\r
623 ParamStatus = X509_VERIFY_PARAM_set1_host (VerifyParam, HostName, 0);\r
624 }\r
625\r
626 return (ParamStatus == 1) ? EFI_SUCCESS : EFI_ABORTED;\r
627}\r
628\r
629/**\r
630 Sets a TLS/SSL session ID to be used during TLS/SSL connect.\r
631\r
632 This function sets a session ID to be used when the TLS/SSL connection is\r
633 to be established.\r
634\r
635 @param[in] Tls Pointer to the TLS object.\r
636 @param[in] SessionId Session ID data used for session resumption.\r
637 @param[in] SessionIdLen Length of Session ID in bytes.\r
638\r
639 @retval EFI_SUCCESS Session ID was set successfully.\r
640 @retval EFI_INVALID_PARAMETER The parameter is invalid.\r
641 @retval EFI_UNSUPPORTED No available session for ID setting.\r
642\r
643**/\r
644EFI_STATUS\r
645EFIAPI\r
646TlsSetSessionId (\r
647 IN VOID *Tls,\r
648 IN UINT8 *SessionId,\r
649 IN UINT16 SessionIdLen\r
650 )\r
651{\r
652 TLS_CONNECTION *TlsConn;\r
653 SSL_SESSION *Session;\r
654\r
655 TlsConn = (TLS_CONNECTION *)Tls;\r
656 Session = NULL;\r
657\r
658 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL) || (SessionId == NULL)) {\r
659 return EFI_INVALID_PARAMETER;\r
660 }\r
661\r
662 Session = SSL_get_session (TlsConn->Ssl);\r
663 if (Session == NULL) {\r
664 return EFI_UNSUPPORTED;\r
665 }\r
666\r
667 SSL_SESSION_set1_id (Session, (const unsigned char *)SessionId, SessionIdLen);\r
668\r
669 return EFI_SUCCESS;\r
670}\r
671\r
672/**\r
673 Adds the CA to the cert store when requesting Server or Client authentication.\r
674\r
675 This function adds the CA certificate to the list of CAs when requesting\r
676 Server or Client authentication for the chosen TLS connection.\r
677\r
678 @param[in] Tls Pointer to the TLS object.\r
679 @param[in] Data Pointer to the data buffer of a DER-encoded binary\r
680 X.509 certificate or PEM-encoded X.509 certificate.\r
681 @param[in] DataSize The size of data buffer in bytes.\r
682\r
683 @retval EFI_SUCCESS The operation succeeded.\r
684 @retval EFI_INVALID_PARAMETER The parameter is invalid.\r
685 @retval EFI_OUT_OF_RESOURCES Required resources could not be allocated.\r
686 @retval EFI_ABORTED Invalid X.509 certificate.\r
687\r
688**/\r
689EFI_STATUS\r
690EFIAPI\r
691TlsSetCaCertificate (\r
692 IN VOID *Tls,\r
693 IN VOID *Data,\r
694 IN UINTN DataSize\r
695 )\r
696{\r
697 BIO *BioCert;\r
698 X509 *Cert;\r
699 X509_STORE *X509Store;\r
700 EFI_STATUS Status;\r
701 TLS_CONNECTION *TlsConn;\r
702 SSL_CTX *SslCtx;\r
703 INTN Ret;\r
704 UINTN ErrorCode;\r
705\r
706 BioCert = NULL;\r
707 Cert = NULL;\r
708 X509Store = NULL;\r
709 Status = EFI_SUCCESS;\r
710 TlsConn = (TLS_CONNECTION *)Tls;\r
711 Ret = 0;\r
712\r
713 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL) || (Data == NULL) || (DataSize == 0)) {\r
714 return EFI_INVALID_PARAMETER;\r
715 }\r
716\r
717 //\r
718 // DER-encoded binary X.509 certificate or PEM-encoded X.509 certificate.\r
719 // Determine whether certificate is from DER encoding, if so, translate it to X509 structure.\r
720 //\r
721 Cert = d2i_X509 (NULL, (const unsigned char **)&Data, (long)DataSize);\r
722 if (Cert == NULL) {\r
723 //\r
724 // Certificate is from PEM encoding.\r
725 //\r
726 BioCert = BIO_new (BIO_s_mem ());\r
727 if (BioCert == NULL) {\r
728 Status = EFI_OUT_OF_RESOURCES;\r
729 goto ON_EXIT;\r
730 }\r
731\r
732 if (BIO_write (BioCert, Data, (UINT32)DataSize) <= 0) {\r
733 Status = EFI_ABORTED;\r
734 goto ON_EXIT;\r
735 }\r
736\r
737 Cert = PEM_read_bio_X509 (BioCert, NULL, NULL, NULL);\r
738 if (Cert == NULL) {\r
739 Status = EFI_ABORTED;\r
740 goto ON_EXIT;\r
741 }\r
742 }\r
743\r
744 SslCtx = SSL_get_SSL_CTX (TlsConn->Ssl);\r
745 X509Store = SSL_CTX_get_cert_store (SslCtx);\r
746 if (X509Store == NULL) {\r
747 Status = EFI_ABORTED;\r
748 goto ON_EXIT;\r
749 }\r
750\r
751 //\r
752 // Add certificate to X509 store\r
753 //\r
754 Ret = X509_STORE_add_cert (X509Store, Cert);\r
755 if (Ret != 1) {\r
756 ErrorCode = ERR_peek_last_error ();\r
757 //\r
758 // Ignore "already in table" errors\r
759 //\r
760 if (!((ERR_GET_FUNC (ErrorCode) == X509_F_X509_STORE_ADD_CERT) &&\r
761 (ERR_GET_REASON (ErrorCode) == X509_R_CERT_ALREADY_IN_HASH_TABLE)))\r
762 {\r
763 Status = EFI_ABORTED;\r
764 goto ON_EXIT;\r
765 }\r
766 }\r
767\r
768ON_EXIT:\r
769 if (BioCert != NULL) {\r
770 BIO_free (BioCert);\r
771 }\r
772\r
773 if (Cert != NULL) {\r
774 X509_free (Cert);\r
775 }\r
776\r
777 return Status;\r
778}\r
779\r
780/**\r
781 Loads the local public certificate into the specified TLS object.\r
782\r
783 This function loads the X.509 certificate into the specified TLS object\r
784 for TLS negotiation.\r
785\r
786 @param[in] Tls Pointer to the TLS object.\r
787 @param[in] Data Pointer to the data buffer of a DER-encoded binary\r
788 X.509 certificate or PEM-encoded X.509 certificate.\r
789 @param[in] DataSize The size of data buffer in bytes.\r
790\r
791 @retval EFI_SUCCESS The operation succeeded.\r
792 @retval EFI_INVALID_PARAMETER The parameter is invalid.\r
793 @retval EFI_OUT_OF_RESOURCES Required resources could not be allocated.\r
794 @retval EFI_ABORTED Invalid X.509 certificate.\r
795\r
796**/\r
797EFI_STATUS\r
798EFIAPI\r
799TlsSetHostPublicCert (\r
800 IN VOID *Tls,\r
801 IN VOID *Data,\r
802 IN UINTN DataSize\r
803 )\r
804{\r
805 BIO *BioCert;\r
806 X509 *Cert;\r
807 EFI_STATUS Status;\r
808 TLS_CONNECTION *TlsConn;\r
809\r
810 BioCert = NULL;\r
811 Cert = NULL;\r
812 Status = EFI_SUCCESS;\r
813 TlsConn = (TLS_CONNECTION *)Tls;\r
814\r
815 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL) || (Data == NULL) || (DataSize == 0)) {\r
816 return EFI_INVALID_PARAMETER;\r
817 }\r
818\r
819 //\r
820 // DER-encoded binary X.509 certificate or PEM-encoded X.509 certificate.\r
821 // Determine whether certificate is from DER encoding, if so, translate it to X509 structure.\r
822 //\r
823 Cert = d2i_X509 (NULL, (const unsigned char **)&Data, (long)DataSize);\r
824 if (Cert == NULL) {\r
825 //\r
826 // Certificate is from PEM encoding.\r
827 //\r
828 BioCert = BIO_new (BIO_s_mem ());\r
829 if (BioCert == NULL) {\r
830 Status = EFI_OUT_OF_RESOURCES;\r
831 goto ON_EXIT;\r
832 }\r
833\r
834 if (BIO_write (BioCert, Data, (UINT32)DataSize) <= 0) {\r
835 Status = EFI_ABORTED;\r
836 goto ON_EXIT;\r
837 }\r
838\r
839 Cert = PEM_read_bio_X509 (BioCert, NULL, NULL, NULL);\r
840 if (Cert == NULL) {\r
841 Status = EFI_ABORTED;\r
842 goto ON_EXIT;\r
843 }\r
844 }\r
845\r
846 if (SSL_use_certificate (TlsConn->Ssl, Cert) != 1) {\r
847 Status = EFI_ABORTED;\r
848 goto ON_EXIT;\r
849 }\r
850\r
851ON_EXIT:\r
852 if (BioCert != NULL) {\r
853 BIO_free (BioCert);\r
854 }\r
855\r
856 if (Cert != NULL) {\r
857 X509_free (Cert);\r
858 }\r
859\r
860 return Status;\r
861}\r
862\r
863/**\r
864 Adds the local private key to the specified TLS object.\r
865\r
866 This function adds the local private key (DER-encoded or PEM-encoded or PKCS#8 private\r
867 key) into the specified TLS object for TLS negotiation.\r
868\r
869 @param[in] Tls Pointer to the TLS object.\r
870 @param[in] Data Pointer to the data buffer of a DER-encoded or PEM-encoded\r
871 or PKCS#8 private key.\r
872 @param[in] DataSize The size of data buffer in bytes.\r
873 @param[in] Password Pointer to NULL-terminated private key password, set it to NULL\r
874 if private key not encrypted.\r
875\r
876 @retval EFI_SUCCESS The operation succeeded.\r
877 @retval EFI_UNSUPPORTED This function is not supported.\r
878 @retval EFI_ABORTED Invalid private key data.\r
879\r
880**/\r
881EFI_STATUS\r
882EFIAPI\r
883TlsSetHostPrivateKeyEx (\r
884 IN VOID *Tls,\r
885 IN VOID *Data,\r
886 IN UINTN DataSize,\r
887 IN VOID *Password OPTIONAL\r
888 )\r
889{\r
890 TLS_CONNECTION *TlsConn;\r
891 BIO *Bio;\r
892 EVP_PKEY *Pkey;\r
893 BOOLEAN Verify;\r
894\r
895 TlsConn = (TLS_CONNECTION *)Tls;\r
896\r
897 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL) || (Data == NULL) || (DataSize == 0)) {\r
898 return EFI_INVALID_PARAMETER;\r
899 }\r
900\r
901 // Try to parse the private key in DER format or un-encrypted PKC#8\r
902 if (SSL_use_PrivateKey_ASN1 (\r
903 EVP_PKEY_RSA,\r
904 TlsConn->Ssl,\r
905 Data,\r
906 (long)DataSize\r
907 ) == 1)\r
908 {\r
909 goto verify;\r
910 }\r
911\r
912 if (SSL_use_PrivateKey_ASN1 (\r
913 EVP_PKEY_DSA,\r
914 TlsConn->Ssl,\r
915 Data,\r
916 (long)DataSize\r
917 ) == 1)\r
918 {\r
919 goto verify;\r
920 }\r
921\r
922 if (SSL_use_PrivateKey_ASN1 (\r
923 EVP_PKEY_EC,\r
924 TlsConn->Ssl,\r
925 Data,\r
926 (long)DataSize\r
927 ) == 1)\r
928 {\r
929 goto verify;\r
930 }\r
931\r
932 // Try to parse the private key in PEM format or encrypted PKC#8\r
933 Bio = BIO_new_mem_buf (Data, (int)DataSize);\r
934 if (Bio != NULL) {\r
935 Verify = FALSE;\r
936 Pkey = PEM_read_bio_PrivateKey (Bio, NULL, NULL, Password);\r
937 if ((Pkey != NULL) && (SSL_use_PrivateKey (TlsConn->Ssl, Pkey) == 1)) {\r
938 Verify = TRUE;\r
939 }\r
940\r
941 EVP_PKEY_free (Pkey);\r
942 BIO_free (Bio);\r
943\r
944 if (Verify) {\r
945 goto verify;\r
946 }\r
947 }\r
948\r
949 return EFI_ABORTED;\r
950\r
951verify:\r
952 if (SSL_check_private_key (TlsConn->Ssl) == 1) {\r
953 return EFI_SUCCESS;\r
954 }\r
955\r
956 return EFI_ABORTED;\r
957}\r
958\r
959/**\r
960 Adds the local private key to the specified TLS object.\r
961\r
962 This function adds the local private key (DER-encoded or PEM-encoded or PKCS#8 private\r
963 key) into the specified TLS object for TLS negotiation.\r
964\r
965 @param[in] Tls Pointer to the TLS object.\r
966 @param[in] Data Pointer to the data buffer of a DER-encoded or PEM-encoded\r
967 or PKCS#8 private key.\r
968 @param[in] DataSize The size of data buffer in bytes.\r
969\r
970 @retval EFI_SUCCESS The operation succeeded.\r
971 @retval EFI_UNSUPPORTED This function is not supported.\r
972 @retval EFI_ABORTED Invalid private key data.\r
973\r
974**/\r
975EFI_STATUS\r
976EFIAPI\r
977TlsSetHostPrivateKey (\r
978 IN VOID *Tls,\r
979 IN VOID *Data,\r
980 IN UINTN DataSize\r
981 )\r
982{\r
983 return TlsSetHostPrivateKeyEx (Tls, Data, DataSize, NULL);\r
984}\r
985\r
986/**\r
987 Adds the CA-supplied certificate revocation list for certificate validation.\r
988\r
989 This function adds the CA-supplied certificate revocation list data for\r
990 certificate validity checking.\r
991\r
992 @param[in] Data Pointer to the data buffer of a DER-encoded CRL data.\r
993 @param[in] DataSize The size of data buffer in bytes.\r
994\r
995 @retval EFI_SUCCESS The operation succeeded.\r
996 @retval EFI_UNSUPPORTED This function is not supported.\r
997 @retval EFI_ABORTED Invalid CRL data.\r
998\r
999**/\r
1000EFI_STATUS\r
1001EFIAPI\r
1002TlsSetCertRevocationList (\r
1003 IN VOID *Data,\r
1004 IN UINTN DataSize\r
1005 )\r
1006{\r
1007 return EFI_UNSUPPORTED;\r
1008}\r
1009\r
1010/**\r
1011 Set the signature algorithm list to used by the TLS object.\r
1012\r
1013 This function sets the signature algorithms for use by a specified TLS object.\r
1014\r
1015 @param[in] Tls Pointer to a TLS object.\r
1016 @param[in] Data Array of UINT8 of signature algorithms. The array consists of\r
1017 pairs of the hash algorithm and the signature algorithm as defined\r
1018 in RFC 5246\r
1019 @param[in] DataSize The length the SignatureAlgoList. Must be divisible by 2.\r
1020\r
1021 @retval EFI_SUCCESS The signature algorithm list was set successfully.\r
1022 @retval EFI_INVALID_PARAMETER The parameters are invalid.\r
1023 @retval EFI_UNSUPPORTED No supported TLS signature algorithm was found in SignatureAlgoList\r
1024 @retval EFI_OUT_OF_RESOURCES Memory allocation failed.\r
1025\r
1026**/\r
1027EFI_STATUS\r
1028EFIAPI\r
1029TlsSetSignatureAlgoList (\r
1030 IN VOID *Tls,\r
1031 IN UINT8 *Data,\r
1032 IN UINTN DataSize\r
1033 )\r
1034{\r
1035 TLS_CONNECTION *TlsConn;\r
1036 UINTN Index;\r
1037 UINTN SignAlgoStrSize;\r
1038 CHAR8 *SignAlgoStr;\r
1039 CHAR8 *Pos;\r
1040 UINT8 *SignatureAlgoList;\r
1041 EFI_STATUS Status;\r
1042\r
1043 TlsConn = (TLS_CONNECTION *)Tls;\r
1044\r
1045 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL) || (Data == NULL) || (DataSize < 3) ||\r
1046 ((DataSize % 2) == 0) || (Data[0] != DataSize - 1))\r
1047 {\r
1048 return EFI_INVALID_PARAMETER;\r
1049 }\r
1050\r
1051 SignatureAlgoList = Data + 1;\r
1052 SignAlgoStrSize = 0;\r
1053 for (Index = 0; Index < Data[0]; Index += 2) {\r
1054 CONST CHAR8 *Tmp;\r
1055\r
1056 if (SignatureAlgoList[Index] >= ARRAY_SIZE (TlsHashAlgoToName)) {\r
1057 return EFI_INVALID_PARAMETER;\r
1058 }\r
1059\r
1060 Tmp = TlsHashAlgoToName[SignatureAlgoList[Index]].Name;\r
1061 if (!Tmp) {\r
1062 return EFI_INVALID_PARAMETER;\r
1063 }\r
1064\r
1065 // Add 1 for the '+'\r
1066 SignAlgoStrSize += AsciiStrLen (Tmp) + 1;\r
1067\r
1068 if (SignatureAlgoList[Index + 1] >= ARRAY_SIZE (TlsSignatureAlgoToName)) {\r
1069 return EFI_INVALID_PARAMETER;\r
1070 }\r
1071\r
1072 Tmp = TlsSignatureAlgoToName[SignatureAlgoList[Index + 1]].Name;\r
1073 if (!Tmp) {\r
1074 return EFI_INVALID_PARAMETER;\r
1075 }\r
1076\r
1077 // Add 1 for the ':' or for the NULL terminator\r
1078 SignAlgoStrSize += AsciiStrLen (Tmp) + 1;\r
1079 }\r
1080\r
1081 if (!SignAlgoStrSize) {\r
1082 return EFI_UNSUPPORTED;\r
1083 }\r
1084\r
1085 SignAlgoStr = AllocatePool (SignAlgoStrSize);\r
1086 if (SignAlgoStr == NULL) {\r
1087 return EFI_OUT_OF_RESOURCES;\r
1088 }\r
1089\r
1090 Pos = SignAlgoStr;\r
1091 for (Index = 0; Index < Data[0]; Index += 2) {\r
1092 CONST CHAR8 *Tmp;\r
1093\r
1094 Tmp = TlsHashAlgoToName[SignatureAlgoList[Index]].Name;\r
1095 CopyMem (Pos, Tmp, AsciiStrLen (Tmp));\r
1096 Pos += AsciiStrLen (Tmp);\r
1097 *Pos++ = '+';\r
1098\r
1099 Tmp = TlsSignatureAlgoToName[SignatureAlgoList[Index + 1]].Name;\r
1100 CopyMem (Pos, Tmp, AsciiStrLen (Tmp));\r
1101 Pos += AsciiStrLen (Tmp);\r
1102 *Pos++ = ':';\r
1103 }\r
1104\r
1105 *(Pos - 1) = '\0';\r
1106\r
1107 if (SSL_set1_sigalgs_list (TlsConn->Ssl, SignAlgoStr) < 1) {\r
1108 Status = EFI_INVALID_PARAMETER;\r
1109 } else {\r
1110 Status = EFI_SUCCESS;\r
1111 }\r
1112\r
1113 FreePool (SignAlgoStr);\r
1114 return Status;\r
1115}\r
1116\r
1117/**\r
1118 Set the EC curve to be used for TLS flows\r
1119\r
1120 This function sets the EC curve to be used for TLS flows.\r
1121\r
1122 @param[in] Tls Pointer to a TLS object.\r
1123 @param[in] Data An EC named curve as defined in section 5.1.1 of RFC 4492.\r
1124 @param[in] DataSize Size of Data, it should be sizeof (UINT32)\r
1125\r
1126 @retval EFI_SUCCESS The EC curve was set successfully.\r
1127 @retval EFI_INVALID_PARAMETER The parameters are invalid.\r
1128 @retval EFI_UNSUPPORTED The requested TLS EC curve is not supported\r
1129\r
1130**/\r
1131EFI_STATUS\r
1132EFIAPI\r
1133TlsSetEcCurve (\r
1134 IN VOID *Tls,\r
1135 IN UINT8 *Data,\r
1136 IN UINTN DataSize\r
1137 )\r
1138{\r
1139 #if !FixedPcdGetBool (PcdOpensslEcEnabled)\r
1140 return EFI_UNSUPPORTED;\r
1141 #else\r
1142 TLS_CONNECTION *TlsConn;\r
1143 EC_KEY *EcKey;\r
1144 INT32 Nid;\r
1145 INT32 Ret;\r
1146\r
1147 TlsConn = (TLS_CONNECTION *)Tls;\r
1148\r
1149 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL) || (Data == NULL) || (DataSize != sizeof (UINT32))) {\r
1150 return EFI_INVALID_PARAMETER;\r
1151 }\r
1152\r
1153 switch (*((UINT32 *)Data)) {\r
1154 case TlsEcNamedCurveSecp256r1:\r
1155 return EFI_UNSUPPORTED;\r
1156 case TlsEcNamedCurveSecp384r1:\r
1157 Nid = NID_secp384r1;\r
1158 break;\r
1159 case TlsEcNamedCurveSecp521r1:\r
1160 Nid = NID_secp521r1;\r
1161 break;\r
1162 case TlsEcNamedCurveX25519:\r
1163 Nid = NID_X25519;\r
1164 break;\r
1165 case TlsEcNamedCurveX448:\r
1166 Nid = NID_X448;\r
1167 break;\r
1168 default:\r
1169 return EFI_UNSUPPORTED;\r
1170 }\r
1171\r
1172 if (SSL_set1_curves (TlsConn->Ssl, &Nid, 1) != 1) {\r
1173 return EFI_INVALID_PARAMETER;\r
1174 }\r
1175\r
1176 EcKey = EC_KEY_new_by_curve_name (Nid);\r
1177 if (EcKey == NULL) {\r
1178 return EFI_INVALID_PARAMETER;\r
1179 }\r
1180\r
1181 Ret = SSL_set_tmp_ecdh (TlsConn->Ssl, EcKey);\r
1182 EC_KEY_free (EcKey);\r
1183\r
1184 if (Ret != 1) {\r
1185 return EFI_INVALID_PARAMETER;\r
1186 }\r
1187\r
1188 return EFI_SUCCESS;\r
1189 #endif\r
1190}\r
1191\r
1192/**\r
1193 Gets the protocol version used by the specified TLS connection.\r
1194\r
1195 This function returns the protocol version used by the specified TLS\r
1196 connection.\r
1197\r
1198 If Tls is NULL, then ASSERT().\r
1199\r
1200 @param[in] Tls Pointer to the TLS object.\r
1201\r
1202 @return The protocol version of the specified TLS connection.\r
1203\r
1204**/\r
1205UINT16\r
1206EFIAPI\r
1207TlsGetVersion (\r
1208 IN VOID *Tls\r
1209 )\r
1210{\r
1211 TLS_CONNECTION *TlsConn;\r
1212\r
1213 TlsConn = (TLS_CONNECTION *)Tls;\r
1214\r
1215 ASSERT (TlsConn != NULL);\r
1216\r
1217 return (UINT16)(SSL_version (TlsConn->Ssl));\r
1218}\r
1219\r
1220/**\r
1221 Gets the connection end of the specified TLS connection.\r
1222\r
1223 This function returns the connection end (as client or as server) used by\r
1224 the specified TLS connection.\r
1225\r
1226 If Tls is NULL, then ASSERT().\r
1227\r
1228 @param[in] Tls Pointer to the TLS object.\r
1229\r
1230 @return The connection end used by the specified TLS connection.\r
1231\r
1232**/\r
1233UINT8\r
1234EFIAPI\r
1235TlsGetConnectionEnd (\r
1236 IN VOID *Tls\r
1237 )\r
1238{\r
1239 TLS_CONNECTION *TlsConn;\r
1240\r
1241 TlsConn = (TLS_CONNECTION *)Tls;\r
1242\r
1243 ASSERT (TlsConn != NULL);\r
1244\r
1245 return (UINT8)SSL_is_server (TlsConn->Ssl);\r
1246}\r
1247\r
1248/**\r
1249 Gets the cipher suite used by the specified TLS connection.\r
1250\r
1251 This function returns current cipher suite used by the specified\r
1252 TLS connection.\r
1253\r
1254 @param[in] Tls Pointer to the TLS object.\r
1255 @param[in,out] CipherId The cipher suite used by the TLS object.\r
1256\r
1257 @retval EFI_SUCCESS The cipher suite was returned successfully.\r
1258 @retval EFI_INVALID_PARAMETER The parameter is invalid.\r
1259 @retval EFI_UNSUPPORTED Unsupported cipher suite.\r
1260\r
1261**/\r
1262EFI_STATUS\r
1263EFIAPI\r
1264TlsGetCurrentCipher (\r
1265 IN VOID *Tls,\r
1266 IN OUT UINT16 *CipherId\r
1267 )\r
1268{\r
1269 TLS_CONNECTION *TlsConn;\r
1270 CONST SSL_CIPHER *Cipher;\r
1271\r
1272 TlsConn = (TLS_CONNECTION *)Tls;\r
1273 Cipher = NULL;\r
1274\r
1275 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL) || (CipherId == NULL)) {\r
1276 return EFI_INVALID_PARAMETER;\r
1277 }\r
1278\r
1279 Cipher = SSL_get_current_cipher (TlsConn->Ssl);\r
1280 if (Cipher == NULL) {\r
1281 return EFI_UNSUPPORTED;\r
1282 }\r
1283\r
1284 *CipherId = (SSL_CIPHER_get_id (Cipher)) & 0xFFFF;\r
1285\r
1286 return EFI_SUCCESS;\r
1287}\r
1288\r
1289/**\r
1290 Gets the compression methods used by the specified TLS connection.\r
1291\r
1292 This function returns current integrated compression methods used by\r
1293 the specified TLS connection.\r
1294\r
1295 @param[in] Tls Pointer to the TLS object.\r
1296 @param[in,out] CompressionId The current compression method used by\r
1297 the TLS object.\r
1298\r
1299 @retval EFI_SUCCESS The compression method was returned successfully.\r
1300 @retval EFI_INVALID_PARAMETER The parameter is invalid.\r
1301 @retval EFI_ABORTED Invalid Compression method.\r
1302 @retval EFI_UNSUPPORTED This function is not supported.\r
1303\r
1304**/\r
1305EFI_STATUS\r
1306EFIAPI\r
1307TlsGetCurrentCompressionId (\r
1308 IN VOID *Tls,\r
1309 IN OUT UINT8 *CompressionId\r
1310 )\r
1311{\r
1312 return EFI_UNSUPPORTED;\r
1313}\r
1314\r
1315/**\r
1316 Gets the verification mode currently set in the TLS connection.\r
1317\r
1318 This function returns the peer verification mode currently set in the\r
1319 specified TLS connection.\r
1320\r
1321 If Tls is NULL, then ASSERT().\r
1322\r
1323 @param[in] Tls Pointer to the TLS object.\r
1324\r
1325 @return The verification mode set in the specified TLS connection.\r
1326\r
1327**/\r
1328UINT32\r
1329EFIAPI\r
1330TlsGetVerify (\r
1331 IN VOID *Tls\r
1332 )\r
1333{\r
1334 TLS_CONNECTION *TlsConn;\r
1335\r
1336 TlsConn = (TLS_CONNECTION *)Tls;\r
1337\r
1338 ASSERT (TlsConn != NULL);\r
1339\r
1340 return SSL_get_verify_mode (TlsConn->Ssl);\r
1341}\r
1342\r
1343/**\r
1344 Gets the session ID used by the specified TLS connection.\r
1345\r
1346 This function returns the TLS/SSL session ID currently used by the\r
1347 specified TLS connection.\r
1348\r
1349 @param[in] Tls Pointer to the TLS object.\r
1350 @param[in,out] SessionId Buffer to contain the returned session ID.\r
1351 @param[in,out] SessionIdLen The length of Session ID in bytes.\r
1352\r
1353 @retval EFI_SUCCESS The Session ID was returned successfully.\r
1354 @retval EFI_INVALID_PARAMETER The parameter is invalid.\r
1355 @retval EFI_UNSUPPORTED Invalid TLS/SSL session.\r
1356\r
1357**/\r
1358EFI_STATUS\r
1359EFIAPI\r
1360TlsGetSessionId (\r
1361 IN VOID *Tls,\r
1362 IN OUT UINT8 *SessionId,\r
1363 IN OUT UINT16 *SessionIdLen\r
1364 )\r
1365{\r
1366 TLS_CONNECTION *TlsConn;\r
1367 SSL_SESSION *Session;\r
1368 CONST UINT8 *SslSessionId;\r
1369\r
1370 TlsConn = (TLS_CONNECTION *)Tls;\r
1371 Session = NULL;\r
1372\r
1373 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL) || (SessionId == NULL) || (SessionIdLen == NULL)) {\r
1374 return EFI_INVALID_PARAMETER;\r
1375 }\r
1376\r
1377 Session = SSL_get_session (TlsConn->Ssl);\r
1378 if (Session == NULL) {\r
1379 return EFI_UNSUPPORTED;\r
1380 }\r
1381\r
1382 SslSessionId = SSL_SESSION_get_id (Session, (unsigned int *)SessionIdLen);\r
1383 CopyMem (SessionId, SslSessionId, *SessionIdLen);\r
1384\r
1385 return EFI_SUCCESS;\r
1386}\r
1387\r
1388/**\r
1389 Gets the client random data used in the specified TLS connection.\r
1390\r
1391 This function returns the TLS/SSL client random data currently used in\r
1392 the specified TLS connection.\r
1393\r
1394 @param[in] Tls Pointer to the TLS object.\r
1395 @param[in,out] ClientRandom Buffer to contain the returned client\r
1396 random data (32 bytes).\r
1397\r
1398**/\r
1399VOID\r
1400EFIAPI\r
1401TlsGetClientRandom (\r
1402 IN VOID *Tls,\r
1403 IN OUT UINT8 *ClientRandom\r
1404 )\r
1405{\r
1406 TLS_CONNECTION *TlsConn;\r
1407\r
1408 TlsConn = (TLS_CONNECTION *)Tls;\r
1409\r
1410 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL) || (ClientRandom == NULL)) {\r
1411 return;\r
1412 }\r
1413\r
1414 SSL_get_client_random (TlsConn->Ssl, ClientRandom, SSL3_RANDOM_SIZE);\r
1415}\r
1416\r
1417/**\r
1418 Gets the server random data used in the specified TLS connection.\r
1419\r
1420 This function returns the TLS/SSL server random data currently used in\r
1421 the specified TLS connection.\r
1422\r
1423 @param[in] Tls Pointer to the TLS object.\r
1424 @param[in,out] ServerRandom Buffer to contain the returned server\r
1425 random data (32 bytes).\r
1426\r
1427**/\r
1428VOID\r
1429EFIAPI\r
1430TlsGetServerRandom (\r
1431 IN VOID *Tls,\r
1432 IN OUT UINT8 *ServerRandom\r
1433 )\r
1434{\r
1435 TLS_CONNECTION *TlsConn;\r
1436\r
1437 TlsConn = (TLS_CONNECTION *)Tls;\r
1438\r
1439 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL) || (ServerRandom == NULL)) {\r
1440 return;\r
1441 }\r
1442\r
1443 SSL_get_server_random (TlsConn->Ssl, ServerRandom, SSL3_RANDOM_SIZE);\r
1444}\r
1445\r
1446/**\r
1447 Gets the master key data used in the specified TLS connection.\r
1448\r
1449 This function returns the TLS/SSL master key material currently used in\r
1450 the specified TLS connection.\r
1451\r
1452 @param[in] Tls Pointer to the TLS object.\r
1453 @param[in,out] KeyMaterial Buffer to contain the returned key material.\r
1454\r
1455 @retval EFI_SUCCESS Key material was returned successfully.\r
1456 @retval EFI_INVALID_PARAMETER The parameter is invalid.\r
1457 @retval EFI_UNSUPPORTED Invalid TLS/SSL session.\r
1458\r
1459**/\r
1460EFI_STATUS\r
1461EFIAPI\r
1462TlsGetKeyMaterial (\r
1463 IN VOID *Tls,\r
1464 IN OUT UINT8 *KeyMaterial\r
1465 )\r
1466{\r
1467 TLS_CONNECTION *TlsConn;\r
1468 SSL_SESSION *Session;\r
1469\r
1470 TlsConn = (TLS_CONNECTION *)Tls;\r
1471 Session = NULL;\r
1472\r
1473 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL) || (KeyMaterial == NULL)) {\r
1474 return EFI_INVALID_PARAMETER;\r
1475 }\r
1476\r
1477 Session = SSL_get_session (TlsConn->Ssl);\r
1478\r
1479 if (Session == NULL) {\r
1480 return EFI_UNSUPPORTED;\r
1481 }\r
1482\r
1483 SSL_SESSION_get_master_key (Session, KeyMaterial, SSL3_MASTER_SECRET_SIZE);\r
1484\r
1485 return EFI_SUCCESS;\r
1486}\r
1487\r
1488/**\r
1489 Gets the CA Certificate from the cert store.\r
1490\r
1491 This function returns the CA certificate for the chosen\r
1492 TLS connection.\r
1493\r
1494 @param[in] Tls Pointer to the TLS object.\r
1495 @param[out] Data Pointer to the data buffer to receive the CA\r
1496 certificate data sent to the client.\r
1497 @param[in,out] DataSize The size of data buffer in bytes.\r
1498\r
1499 @retval EFI_SUCCESS The operation succeeded.\r
1500 @retval EFI_UNSUPPORTED This function is not supported.\r
1501 @retval EFI_BUFFER_TOO_SMALL The Data is too small to hold the data.\r
1502\r
1503**/\r
1504EFI_STATUS\r
1505EFIAPI\r
1506TlsGetCaCertificate (\r
1507 IN VOID *Tls,\r
1508 OUT VOID *Data,\r
1509 IN OUT UINTN *DataSize\r
1510 )\r
1511{\r
1512 return EFI_UNSUPPORTED;\r
1513}\r
1514\r
1515/**\r
1516 Gets the local public Certificate set in the specified TLS object.\r
1517\r
1518 This function returns the local public certificate which was currently set\r
1519 in the specified TLS object.\r
1520\r
1521 @param[in] Tls Pointer to the TLS object.\r
1522 @param[out] Data Pointer to the data buffer to receive the local\r
1523 public certificate.\r
1524 @param[in,out] DataSize The size of data buffer in bytes.\r
1525\r
1526 @retval EFI_SUCCESS The operation succeeded.\r
1527 @retval EFI_INVALID_PARAMETER The parameter is invalid.\r
1528 @retval EFI_NOT_FOUND The certificate is not found.\r
1529 @retval EFI_BUFFER_TOO_SMALL The Data is too small to hold the data.\r
1530\r
1531**/\r
1532EFI_STATUS\r
1533EFIAPI\r
1534TlsGetHostPublicCert (\r
1535 IN VOID *Tls,\r
1536 OUT VOID *Data,\r
1537 IN OUT UINTN *DataSize\r
1538 )\r
1539{\r
1540 X509 *Cert;\r
1541 TLS_CONNECTION *TlsConn;\r
1542\r
1543 Cert = NULL;\r
1544 TlsConn = (TLS_CONNECTION *)Tls;\r
1545\r
1546 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL) || (DataSize == NULL) || ((*DataSize != 0) && (Data == NULL))) {\r
1547 return EFI_INVALID_PARAMETER;\r
1548 }\r
1549\r
1550 Cert = SSL_get_certificate (TlsConn->Ssl);\r
1551 if (Cert == NULL) {\r
1552 return EFI_NOT_FOUND;\r
1553 }\r
1554\r
1555 //\r
1556 // Only DER encoding is supported currently.\r
1557 //\r
1558 if (*DataSize < (UINTN)i2d_X509 (Cert, NULL)) {\r
1559 *DataSize = (UINTN)i2d_X509 (Cert, NULL);\r
1560 return EFI_BUFFER_TOO_SMALL;\r
1561 }\r
1562\r
1563 *DataSize = (UINTN)i2d_X509 (Cert, (unsigned char **)&Data);\r
1564\r
1565 return EFI_SUCCESS;\r
1566}\r
1567\r
1568/**\r
1569 Gets the local private key set in the specified TLS object.\r
1570\r
1571 This function returns the local private key data which was currently set\r
1572 in the specified TLS object.\r
1573\r
1574 @param[in] Tls Pointer to the TLS object.\r
1575 @param[out] Data Pointer to the data buffer to receive the local\r
1576 private key data.\r
1577 @param[in,out] DataSize The size of data buffer in bytes.\r
1578\r
1579 @retval EFI_SUCCESS The operation succeeded.\r
1580 @retval EFI_UNSUPPORTED This function is not supported.\r
1581 @retval EFI_BUFFER_TOO_SMALL The Data is too small to hold the data.\r
1582\r
1583**/\r
1584EFI_STATUS\r
1585EFIAPI\r
1586TlsGetHostPrivateKey (\r
1587 IN VOID *Tls,\r
1588 OUT VOID *Data,\r
1589 IN OUT UINTN *DataSize\r
1590 )\r
1591{\r
1592 return EFI_UNSUPPORTED;\r
1593}\r
1594\r
1595/**\r
1596 Gets the CA-supplied certificate revocation list data set in the specified\r
1597 TLS object.\r
1598\r
1599 This function returns the CA-supplied certificate revocation list data which\r
1600 was currently set in the specified TLS object.\r
1601\r
1602 @param[out] Data Pointer to the data buffer to receive the CRL data.\r
1603 @param[in,out] DataSize The size of data buffer in bytes.\r
1604\r
1605 @retval EFI_SUCCESS The operation succeeded.\r
1606 @retval EFI_UNSUPPORTED This function is not supported.\r
1607 @retval EFI_BUFFER_TOO_SMALL The Data is too small to hold the data.\r
1608\r
1609**/\r
1610EFI_STATUS\r
1611EFIAPI\r
1612TlsGetCertRevocationList (\r
1613 OUT VOID *Data,\r
1614 IN OUT UINTN *DataSize\r
1615 )\r
1616{\r
1617 return EFI_UNSUPPORTED;\r
1618}\r
1619\r
1620/**\r
1621 Derive keying material from a TLS connection.\r
1622\r
1623 This function exports keying material using the mechanism described in RFC\r
1624 5705.\r
1625\r
1626 @param[in] Tls Pointer to the TLS object\r
1627 @param[in] Label Description of the key for the PRF function\r
1628 @param[in] Context Optional context\r
1629 @param[in] ContextLen The length of the context value in bytes\r
1630 @param[out] KeyBuffer Buffer to hold the output of the TLS-PRF\r
1631 @param[in] KeyBufferLen The length of the KeyBuffer\r
1632\r
1633 @retval EFI_SUCCESS The operation succeeded.\r
1634 @retval EFI_INVALID_PARAMETER The TLS object is invalid.\r
1635 @retval EFI_PROTOCOL_ERROR Some other error occurred.\r
1636\r
1637**/\r
1638EFI_STATUS\r
1639EFIAPI\r
1640TlsGetExportKey (\r
1641 IN VOID *Tls,\r
1642 IN CONST VOID *Label,\r
1643 IN CONST VOID *Context,\r
1644 IN UINTN ContextLen,\r
1645 OUT VOID *KeyBuffer,\r
1646 IN UINTN KeyBufferLen\r
1647 )\r
1648{\r
1649 TLS_CONNECTION *TlsConn;\r
1650\r
1651 TlsConn = (TLS_CONNECTION *)Tls;\r
1652\r
1653 if ((TlsConn == NULL) || (TlsConn->Ssl == NULL)) {\r
1654 return EFI_INVALID_PARAMETER;\r
1655 }\r
1656\r
1657 return SSL_export_keying_material (\r
1658 TlsConn->Ssl,\r
1659 KeyBuffer,\r
1660 KeyBufferLen,\r
1661 Label,\r
1662 AsciiStrLen (Label),\r
1663 Context,\r
1664 ContextLen,\r
1665 Context != NULL\r
1666 ) == 1 ?\r
1667 EFI_SUCCESS : EFI_PROTOCOL_ERROR;\r
1668}\r
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