1 /* |
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2 * Copyright (c) 2004, 2015, Oracle and/or its affiliates. All rights reserved. |
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3 */ |
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4 |
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5 /* crypto/engine/e_pk11.c */ |
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6 /* |
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7 * This product includes software developed by the OpenSSL Project for |
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8 * use in the OpenSSL Toolkit (http://www.openssl.org/). |
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9 * |
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10 * This project also referenced hw_pkcs11-0.9.7b.patch written by |
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11 * Afchine Madjlessi. |
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12 */ |
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13 /* |
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14 * ==================================================================== |
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15 * Copyright (c) 2000-2001 The OpenSSL Project. All rights reserved. |
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16 * |
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17 * Redistribution and use in source and binary forms, with or without |
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18 * modification, are permitted provided that the following conditions |
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19 * are met: |
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20 * |
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21 * 1. Redistributions of source code must retain the above copyright |
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22 * notice, this list of conditions and the following disclaimer. |
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23 * |
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24 * 2. Redistributions in binary form must reproduce the above copyright |
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25 * notice, this list of conditions and the following disclaimer in |
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26 * the documentation and/or other materials provided with the |
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27 * distribution. |
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28 * |
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29 * 3. All advertising materials mentioning features or use of this |
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30 * software must display the following acknowledgment: |
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31 * "This product includes software developed by the OpenSSL Project |
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32 * for use in the OpenSSL Toolkit. (http://www.OpenSSL.org/)" |
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33 * |
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34 * 4. The names "OpenSSL Toolkit" and "OpenSSL Project" must not be used to |
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35 * endorse or promote products derived from this software without |
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36 * prior written permission. For written permission, please contact |
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37 * [email protected]. |
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38 * |
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39 * 5. Products derived from this software may not be called "OpenSSL" |
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40 * nor may "OpenSSL" appear in their names without prior written |
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41 * permission of the OpenSSL Project. |
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42 * |
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43 * 6. Redistributions of any form whatsoever must retain the following |
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44 * acknowledgment: |
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45 * "This product includes software developed by the OpenSSL Project |
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46 * for use in the OpenSSL Toolkit (http://www.OpenSSL.org/)" |
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47 * |
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48 * THIS SOFTWARE IS PROVIDED BY THE OpenSSL PROJECT ``AS IS'' AND ANY |
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49 * EXPRESSED OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE |
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50 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR |
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51 * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE OpenSSL PROJECT OR |
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52 * ITS CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, |
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53 * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT |
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54 * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; |
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55 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) |
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56 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, |
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57 * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) |
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58 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED |
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59 * OF THE POSSIBILITY OF SUCH DAMAGE. |
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60 * ==================================================================== |
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61 * |
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62 * This product includes cryptographic software written by Eric Young |
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63 * ([email protected]). This product includes software written by Tim |
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64 * Hudson ([email protected]). |
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65 * |
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66 */ |
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67 |
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68 #include <stdio.h> |
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69 #include <stdlib.h> |
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70 #include <string.h> |
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71 #include <sys/types.h> |
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72 #include <unistd.h> |
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73 #include <strings.h> |
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74 |
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75 #include <openssl/e_os2.h> |
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76 #include <openssl/crypto.h> |
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77 #include <openssl/engine.h> |
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78 #include <openssl/dso.h> |
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79 #include <openssl/err.h> |
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80 #include <openssl/bn.h> |
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81 #include <openssl/md5.h> |
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82 #include <openssl/pem.h> |
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83 #ifndef OPENSSL_NO_RSA |
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84 #include <openssl/rsa.h> |
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85 #endif |
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86 #ifndef OPENSSL_NO_DSA |
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87 #include <openssl/dsa.h> |
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88 #endif |
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89 #ifndef OPENSSL_NO_DH |
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90 #include <openssl/dh.h> |
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91 #endif |
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92 #include <openssl/rand.h> |
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93 #include <openssl/objects.h> |
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94 #include <openssl/x509.h> |
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95 #include <openssl/aes.h> |
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96 #include <dlfcn.h> |
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97 #include <pthread.h> |
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98 |
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99 #ifndef OPENSSL_NO_HW |
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100 #ifndef OPENSSL_NO_HW_PK11 |
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101 |
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102 /* label for debug messages printed on stderr */ |
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103 #define PK11_DBG "PKCS#11 ENGINE DEBUG" |
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104 /* prints a lot of debug messages on stderr about slot selection process */ |
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105 #undef DEBUG_SLOT_SELECTION |
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106 /* |
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107 * Solaris specific code. See comment at check_hw_mechanisms() for more |
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108 * information. |
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109 */ |
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110 #if defined(__SVR4) && defined(__sun) |
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111 #define SOLARIS_HW_SLOT_SELECTION |
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112 #endif |
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113 |
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114 #ifdef SOLARIS_HW_SLOT_SELECTION |
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115 #include <sys/auxv.h> |
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116 #endif |
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117 |
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118 #ifdef DEBUG_SLOT_SELECTION |
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119 #define DEBUG_SLOT_SEL(...) fprintf(stderr, __VA_ARGS__) |
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120 #else |
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121 #define DEBUG_SLOT_SEL(...) |
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122 #endif |
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123 |
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124 #include <security/cryptoki.h> |
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125 #include <security/pkcs11.h> |
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126 #include "e_pk11.h" |
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127 #include "e_pk11_uri.h" |
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128 |
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129 static CK_BBOOL pk11_true = CK_TRUE; |
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130 static CK_BBOOL pk11_false = CK_FALSE; |
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131 #define PK11_ENGINE_LIB_NAME "PKCS#11 engine" |
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132 #include "e_pk11_err.c" |
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133 #include "e_pk11_uri.c" |
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134 #include "e_pk11_pub.c" |
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135 |
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136 /* |
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137 * We use this lock to prevent multiple C_Login()s, guard getpassphrase(), |
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138 * uri_struct manipulation, and static token info. All of that is used by the |
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139 * RSA keys by reference feature. |
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140 */ |
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141 pthread_mutex_t *uri_lock = NULL; |
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142 |
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143 #ifdef SOLARIS_HW_SLOT_SELECTION |
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144 /* |
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145 * Tables for symmetric ciphers and digest mechs found in the pkcs11_kernel |
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146 * library. See comment at check_hw_mechanisms() for more information. |
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147 */ |
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148 int *hw_cnids; |
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149 int *hw_dnids; |
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150 #endif /* SOLARIS_HW_SLOT_SELECTION */ |
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151 |
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152 /* PKCS#11 session caches and their locks for all operation types */ |
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153 static PK11_CACHE session_cache[OP_MAX]; |
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154 |
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155 /* |
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156 * We cache the flags so that we do not have to run C_GetTokenInfo() again when |
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157 * logging into the token. |
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158 */ |
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159 CK_FLAGS pubkey_token_flags; |
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160 |
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161 /* |
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162 * As stated in v2.20, 11.7 Object Management Function, in section for |
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163 * C_FindObjectsInit(), at most one search operation may be active at a given |
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164 * time in a given session. Therefore, C_Find{,Init,Final}Objects() should be |
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165 * grouped together to form one atomic search operation. This is already |
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166 * ensured by the property of unique PKCS#11 session handle used for each |
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167 * PK11_SESSION object. |
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168 * |
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169 * This is however not the biggest concern - maintaining consistency of the |
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170 * underlying object store is more important. The same section of the spec also |
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171 * says that one thread can be in the middle of a search operation while another |
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172 * thread destroys the object matching the search template which would result in |
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173 * invalid handle returned from the search operation. |
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174 * |
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175 * Hence, the following locks are used for both protection of the object stores. |
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176 * They are also used for active list protection. |
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177 */ |
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178 pthread_mutex_t *find_lock[OP_MAX] = { NULL }; |
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179 |
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180 /* |
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181 * lists of asymmetric key handles which are active (referenced by at least one |
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182 * PK11_SESSION structure, either held by a thread or present in free_session |
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183 * list) for given algorithm type |
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184 */ |
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185 PK11_active *active_list[OP_MAX] = { NULL }; |
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186 |
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187 /* |
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188 * Create all secret key objects in a global session so that they are available |
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189 * to use for other sessions. These other sessions may be opened or closed |
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190 * without losing the secret key objects. |
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191 */ |
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192 static CK_SESSION_HANDLE global_session = CK_INVALID_HANDLE; |
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193 |
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194 /* Index for the supported ciphers */ |
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195 enum pk11_cipher_id |
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196 { |
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197 PK11_DES_CBC, |
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198 PK11_DES3_CBC, |
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199 PK11_DES_ECB, |
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200 PK11_DES3_ECB, |
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201 PK11_RC4, |
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202 PK11_AES_128_CBC, |
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203 PK11_AES_192_CBC, |
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204 PK11_AES_256_CBC, |
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205 PK11_AES_128_ECB, |
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206 PK11_AES_192_ECB, |
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207 PK11_AES_256_ECB, |
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208 PK11_BLOWFISH_CBC, |
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209 PK11_AES_128_CTR, |
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210 PK11_AES_192_CTR, |
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211 PK11_AES_256_CTR, |
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212 PK11_CIPHER_MAX |
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213 }; |
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214 |
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215 /* Index for the supported digests */ |
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216 enum pk11_digest_id |
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217 { |
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218 PK11_MD5, |
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219 PK11_SHA1, |
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220 PK11_SHA224, |
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221 PK11_SHA256, |
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222 PK11_SHA384, |
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223 PK11_SHA512, |
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224 PK11_DIGEST_MAX |
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225 }; |
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226 |
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227 typedef struct PK11_CIPHER_st |
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228 { |
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229 enum pk11_cipher_id id; |
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230 int nid; |
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231 int iv_len; |
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232 int min_key_len; |
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233 int max_key_len; |
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234 CK_KEY_TYPE key_type; |
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235 CK_MECHANISM_TYPE mech_type; |
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236 } PK11_CIPHER; |
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237 |
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238 typedef struct PK11_DIGEST_st |
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239 { |
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240 enum pk11_digest_id id; |
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241 int nid; |
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242 CK_MECHANISM_TYPE mech_type; |
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243 } PK11_DIGEST; |
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244 |
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245 /* ENGINE level stuff */ |
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246 static int pk11_init(ENGINE *e); |
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247 static int pk11_library_init(ENGINE *e); |
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248 static int pk11_finish(ENGINE *e); |
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249 static int pk11_ctrl(ENGINE *e, int cmd, long i, void *p, void (*f)()); |
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250 static int pk11_destroy(ENGINE *e); |
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251 |
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252 /* RAND stuff */ |
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253 static void pk11_rand_seed(const void *buf, int num); |
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254 static void pk11_rand_add(const void *buf, int num, double add_entropy); |
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255 static void pk11_rand_cleanup(void); |
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256 static int pk11_rand_bytes(unsigned char *buf, int num); |
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257 static int pk11_rand_status(void); |
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258 |
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259 /* These functions are also used in other files */ |
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260 PK11_SESSION *pk11_get_session(PK11_OPTYPE optype); |
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261 void pk11_return_session(PK11_SESSION *sp, PK11_OPTYPE optype); |
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262 |
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263 /* active list manipulation functions used in this file */ |
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264 extern int pk11_active_delete(CK_OBJECT_HANDLE h, PK11_OPTYPE type); |
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265 extern void pk11_free_active_list(PK11_OPTYPE type); |
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266 |
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267 #ifndef OPENSSL_NO_RSA |
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268 int pk11_destroy_rsa_key_objects(PK11_SESSION *session); |
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269 int pk11_destroy_rsa_object_pub(PK11_SESSION *sp, CK_BBOOL uselock); |
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270 int pk11_destroy_rsa_object_priv(PK11_SESSION *sp, CK_BBOOL uselock); |
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271 #endif |
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272 #ifndef OPENSSL_NO_DSA |
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273 int pk11_destroy_dsa_key_objects(PK11_SESSION *session); |
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274 int pk11_destroy_dsa_object_pub(PK11_SESSION *sp, CK_BBOOL uselock); |
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275 int pk11_destroy_dsa_object_priv(PK11_SESSION *sp, CK_BBOOL uselock); |
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276 #endif |
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277 #ifndef OPENSSL_NO_DH |
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278 int pk11_destroy_dh_key_objects(PK11_SESSION *session); |
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279 int pk11_destroy_dh_object(PK11_SESSION *session, CK_BBOOL uselock); |
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280 #endif |
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281 |
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282 /* Local helper functions */ |
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283 static int pk11_free_all_sessions(void); |
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284 static int pk11_free_session_list(PK11_OPTYPE optype); |
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285 static int pk11_setup_session(PK11_SESSION *sp, PK11_OPTYPE optype); |
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286 static int pk11_destroy_cipher_key_objects(PK11_SESSION *session); |
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287 static int pk11_destroy_object(CK_SESSION_HANDLE handle, CK_OBJECT_HANDLE oh, |
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288 CK_BBOOL persistent); |
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289 static const char *get_PK11_LIBNAME(void); |
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290 static void free_PK11_LIBNAME(void); |
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291 static long set_PK11_LIBNAME(const char *name); |
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292 |
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293 /* Symmetric cipher and digest support functions */ |
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294 static int cipher_nid_to_pk11(int nid); |
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295 static int pk11_usable_ciphers(const int **nids); |
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296 static int pk11_usable_digests(const int **nids); |
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297 static int pk11_cipher_init(EVP_CIPHER_CTX *ctx, const unsigned char *key, |
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298 const unsigned char *iv, int enc); |
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299 static int pk11_cipher_final(PK11_SESSION *sp); |
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300 static int pk11_cipher_do_cipher(EVP_CIPHER_CTX *ctx, unsigned char *out, |
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301 const unsigned char *in, size_t inl); |
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302 static int pk11_cipher_cleanup(EVP_CIPHER_CTX *ctx); |
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303 static int pk11_engine_ciphers(ENGINE *e, const EVP_CIPHER **cipher, |
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304 const int **nids, int nid); |
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305 static int pk11_engine_digests(ENGINE *e, const EVP_MD **digest, |
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306 const int **nids, int nid); |
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307 static CK_OBJECT_HANDLE pk11_get_cipher_key(EVP_CIPHER_CTX *ctx, |
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308 const unsigned char *key, CK_KEY_TYPE key_type, PK11_SESSION *sp); |
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309 static int check_new_cipher_key(PK11_SESSION *sp, const unsigned char *key, |
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310 int key_len); |
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311 static int md_nid_to_pk11(int nid); |
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312 static int pk11_digest_init(EVP_MD_CTX *ctx); |
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313 static int pk11_digest_update(EVP_MD_CTX *ctx, const void *data, |
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314 size_t count); |
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315 static int pk11_digest_final(EVP_MD_CTX *ctx, unsigned char *md); |
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316 static int pk11_digest_copy(EVP_MD_CTX *to, const EVP_MD_CTX *from); |
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317 static int pk11_digest_cleanup(EVP_MD_CTX *ctx); |
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318 |
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319 static int pk11_choose_slots(int *any_slot_found); |
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320 static void pk11_choose_rand_slot(CK_TOKEN_INFO token_info, |
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321 CK_SLOT_ID current_slot); |
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322 static void pk11_choose_pubkey_slot(CK_MECHANISM_INFO mech_info, |
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323 CK_TOKEN_INFO token_info, CK_SLOT_ID current_slot, CK_RV rv, |
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324 int best_number_of_mechs, CK_SLOT_ID best_pubkey_slot_sofar); |
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325 static void pk11_choose_cipher_digest(int *local_cipher_nids, |
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326 int *local_digest_nids, CK_FUNCTION_LIST_PTR pflist, |
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327 CK_SLOT_ID current_slot); |
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328 static void pk11_find_symmetric_ciphers(CK_FUNCTION_LIST_PTR pflist, |
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329 CK_SLOT_ID current_slot, int *current_slot_n_cipher, |
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330 int *local_cipher_nids); |
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331 static void pk11_find_digests(CK_FUNCTION_LIST_PTR pflist, |
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332 CK_SLOT_ID current_slot, int *current_slot_n_digest, |
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333 int *local_digest_nids); |
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334 static void pk11_get_symmetric_cipher(CK_FUNCTION_LIST_PTR, int slot_id, |
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335 int *current_slot_n_cipher, int *local_cipher_nids, |
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336 PK11_CIPHER *cipher); |
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337 static void pk11_get_digest(CK_FUNCTION_LIST_PTR pflist, int slot_id, |
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338 int *current_slot_n_digest, int *local_digest_nids, |
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339 PK11_DIGEST *digest); |
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340 |
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341 static int pk11_init_all_locks(void); |
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342 static void pk11_free_all_locks(void); |
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343 |
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344 #ifdef SOLARIS_HW_SLOT_SELECTION |
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345 static int check_hw_mechanisms(void); |
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346 static int nid_in_table(int nid, int *nid_table); |
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347 static int hw_aes_instruction_set_present(void); |
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348 #endif /* SOLARIS_HW_SLOT_SELECTION */ |
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349 |
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350 #define TRY_OBJ_DESTROY(sp, obj_hdl, retval, uselock, alg_type) \ |
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351 { \ |
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352 if (uselock) \ |
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353 LOCK_OBJSTORE(alg_type); \ |
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354 if (pk11_active_delete(obj_hdl, alg_type) == 1) \ |
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355 { \ |
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356 retval = pk11_destroy_object(sp->session, obj_hdl, \ |
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357 sp->persistent); \ |
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358 } \ |
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359 if (uselock) \ |
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360 UNLOCK_OBJSTORE(alg_type); \ |
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361 } |
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362 |
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363 static int cipher_nids[PK11_CIPHER_MAX]; |
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364 static int digest_nids[PK11_DIGEST_MAX]; |
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365 static int cipher_count = 0; |
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366 static int digest_count = 0; |
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367 static CK_BBOOL pk11_have_rsa = CK_FALSE; |
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368 static CK_BBOOL pk11_have_dsa = CK_FALSE; |
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369 static CK_BBOOL pk11_have_dh = CK_FALSE; |
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370 static CK_BBOOL pk11_have_random = CK_FALSE; |
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371 |
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372 /* |
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373 * Static list of ciphers. |
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374 * Note, that ciphers array is indexed by member PK11_CIPHER.id, |
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375 * thus ciphers[i].id == i |
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376 * Rows must be kept in sync with enum pk11_cipher_id. |
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377 */ |
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378 static PK11_CIPHER ciphers[] = |
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379 { |
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380 { PK11_DES_CBC, NID_des_cbc, 8, 8, 8, |
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381 CKK_DES, CKM_DES_CBC, }, |
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382 { PK11_DES3_CBC, NID_des_ede3_cbc, 8, 24, 24, |
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383 CKK_DES3, CKM_DES3_CBC, }, |
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384 { PK11_DES_ECB, NID_des_ecb, 0, 8, 8, |
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385 CKK_DES, CKM_DES_ECB, }, |
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386 { PK11_DES3_ECB, NID_des_ede3_ecb, 0, 24, 24, |
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387 CKK_DES3, CKM_DES3_ECB, }, |
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388 { PK11_RC4, NID_rc4, 0, 16, 256, |
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389 CKK_RC4, CKM_RC4, }, |
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390 { PK11_AES_128_CBC, NID_aes_128_cbc, 16, 16, 16, |
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391 CKK_AES, CKM_AES_CBC, }, |
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392 { PK11_AES_192_CBC, NID_aes_192_cbc, 16, 24, 24, |
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393 CKK_AES, CKM_AES_CBC, }, |
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394 { PK11_AES_256_CBC, NID_aes_256_cbc, 16, 32, 32, |
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395 CKK_AES, CKM_AES_CBC, }, |
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396 { PK11_AES_128_ECB, NID_aes_128_ecb, 0, 16, 16, |
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397 CKK_AES, CKM_AES_ECB, }, |
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398 { PK11_AES_192_ECB, NID_aes_192_ecb, 0, 24, 24, |
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399 CKK_AES, CKM_AES_ECB, }, |
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400 { PK11_AES_256_ECB, NID_aes_256_ecb, 0, 32, 32, |
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401 CKK_AES, CKM_AES_ECB, }, |
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402 { PK11_BLOWFISH_CBC, NID_bf_cbc, 8, 16, 16, |
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403 CKK_BLOWFISH, CKM_BLOWFISH_CBC, }, |
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404 { PK11_AES_128_CTR, NID_aes_128_ctr, 16, 16, 16, |
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405 CKK_AES, CKM_AES_CTR, }, |
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406 { PK11_AES_192_CTR, NID_aes_192_ctr, 16, 24, 24, |
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407 CKK_AES, CKM_AES_CTR, }, |
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408 { PK11_AES_256_CTR, NID_aes_256_ctr, 16, 32, 32, |
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409 CKK_AES, CKM_AES_CTR, }, |
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410 }; |
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411 |
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412 /* |
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413 * Static list of digests. |
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414 * Note, that digests array is indexed by member PK11_DIGEST.id, |
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415 * thus digests[i].id == i |
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416 * Rows must be kept in sync with enum pk11_digest_id. |
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417 */ |
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418 static PK11_DIGEST digests[] = |
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419 { |
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420 {PK11_MD5, NID_md5, CKM_MD5, }, |
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421 {PK11_SHA1, NID_sha1, CKM_SHA_1, }, |
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422 {PK11_SHA224, NID_sha224, CKM_SHA224, }, |
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423 {PK11_SHA256, NID_sha256, CKM_SHA256, }, |
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424 {PK11_SHA384, NID_sha384, CKM_SHA384, }, |
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425 {PK11_SHA512, NID_sha512, CKM_SHA512, }, |
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426 {0, NID_undef, 0xFFFF, }, |
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427 }; |
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428 |
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429 /* |
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430 * Structure to be used for the cipher_data/md_data in |
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431 * EVP_CIPHER_CTX/EVP_MD_CTX structures in order to use the same pk11 |
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432 * session in multiple cipher_update calls |
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433 */ |
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434 typedef struct PK11_CIPHER_STATE_st |
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435 { |
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436 PK11_SESSION *sp; |
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437 } PK11_CIPHER_STATE; |
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438 |
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439 |
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440 /* |
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441 * libcrypto EVP stuff - this is how we get wired to EVP so the engine gets |
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442 * called when libcrypto requests a cipher NID. |
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443 * |
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444 * Note how the PK11_CIPHER_STATE is used here. |
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445 */ |
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446 |
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447 /* DES CBC EVP */ |
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448 static const EVP_CIPHER pk11_des_cbc = |
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449 { |
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450 NID_des_cbc, |
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451 8, 8, 8, |
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452 EVP_CIPH_CBC_MODE, |
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453 pk11_cipher_init, |
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454 pk11_cipher_do_cipher, |
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455 pk11_cipher_cleanup, |
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456 sizeof (PK11_CIPHER_STATE), |
|
457 EVP_CIPHER_set_asn1_iv, |
|
458 EVP_CIPHER_get_asn1_iv, |
|
459 NULL |
|
460 }; |
|
461 |
|
462 /* 3DES CBC EVP */ |
|
463 static const EVP_CIPHER pk11_3des_cbc = |
|
464 { |
|
465 NID_des_ede3_cbc, |
|
466 8, 24, 8, |
|
467 EVP_CIPH_CBC_MODE, |
|
468 pk11_cipher_init, |
|
469 pk11_cipher_do_cipher, |
|
470 pk11_cipher_cleanup, |
|
471 sizeof (PK11_CIPHER_STATE), |
|
472 EVP_CIPHER_set_asn1_iv, |
|
473 EVP_CIPHER_get_asn1_iv, |
|
474 NULL |
|
475 }; |
|
476 |
|
477 /* |
|
478 * ECB modes don't use an Initial Vector so that's why set_asn1_parameters and |
|
479 * get_asn1_parameters fields are set to NULL. |
|
480 */ |
|
481 static const EVP_CIPHER pk11_des_ecb = |
|
482 { |
|
483 NID_des_ecb, |
|
484 8, 8, 8, |
|
485 EVP_CIPH_ECB_MODE, |
|
486 pk11_cipher_init, |
|
487 pk11_cipher_do_cipher, |
|
488 pk11_cipher_cleanup, |
|
489 sizeof (PK11_CIPHER_STATE), |
|
490 NULL, |
|
491 NULL, |
|
492 NULL |
|
493 }; |
|
494 |
|
495 static const EVP_CIPHER pk11_3des_ecb = |
|
496 { |
|
497 NID_des_ede3_ecb, |
|
498 8, 24, 8, |
|
499 EVP_CIPH_ECB_MODE, |
|
500 pk11_cipher_init, |
|
501 pk11_cipher_do_cipher, |
|
502 pk11_cipher_cleanup, |
|
503 sizeof (PK11_CIPHER_STATE), |
|
504 NULL, |
|
505 NULL, |
|
506 NULL |
|
507 }; |
|
508 |
|
509 |
|
510 static const EVP_CIPHER pk11_aes_128_cbc = |
|
511 { |
|
512 NID_aes_128_cbc, |
|
513 16, 16, 16, |
|
514 EVP_CIPH_CBC_MODE, |
|
515 pk11_cipher_init, |
|
516 pk11_cipher_do_cipher, |
|
517 pk11_cipher_cleanup, |
|
518 sizeof (PK11_CIPHER_STATE), |
|
519 EVP_CIPHER_set_asn1_iv, |
|
520 EVP_CIPHER_get_asn1_iv, |
|
521 NULL |
|
522 }; |
|
523 |
|
524 static const EVP_CIPHER pk11_aes_192_cbc = |
|
525 { |
|
526 NID_aes_192_cbc, |
|
527 16, 24, 16, |
|
528 EVP_CIPH_CBC_MODE, |
|
529 pk11_cipher_init, |
|
530 pk11_cipher_do_cipher, |
|
531 pk11_cipher_cleanup, |
|
532 sizeof (PK11_CIPHER_STATE), |
|
533 EVP_CIPHER_set_asn1_iv, |
|
534 EVP_CIPHER_get_asn1_iv, |
|
535 NULL |
|
536 }; |
|
537 |
|
538 static const EVP_CIPHER pk11_aes_256_cbc = |
|
539 { |
|
540 NID_aes_256_cbc, |
|
541 16, 32, 16, |
|
542 EVP_CIPH_CBC_MODE, |
|
543 pk11_cipher_init, |
|
544 pk11_cipher_do_cipher, |
|
545 pk11_cipher_cleanup, |
|
546 sizeof (PK11_CIPHER_STATE), |
|
547 EVP_CIPHER_set_asn1_iv, |
|
548 EVP_CIPHER_get_asn1_iv, |
|
549 NULL |
|
550 }; |
|
551 |
|
552 /* |
|
553 * ECB modes don't use IV so that's why set_asn1_parameters and |
|
554 * get_asn1_parameters are set to NULL. |
|
555 */ |
|
556 static const EVP_CIPHER pk11_aes_128_ecb = |
|
557 { |
|
558 NID_aes_128_ecb, |
|
559 16, 16, 0, |
|
560 EVP_CIPH_ECB_MODE, |
|
561 pk11_cipher_init, |
|
562 pk11_cipher_do_cipher, |
|
563 pk11_cipher_cleanup, |
|
564 sizeof (PK11_CIPHER_STATE), |
|
565 NULL, |
|
566 NULL, |
|
567 NULL |
|
568 }; |
|
569 |
|
570 static const EVP_CIPHER pk11_aes_192_ecb = |
|
571 { |
|
572 NID_aes_192_ecb, |
|
573 16, 24, 0, |
|
574 EVP_CIPH_ECB_MODE, |
|
575 pk11_cipher_init, |
|
576 pk11_cipher_do_cipher, |
|
577 pk11_cipher_cleanup, |
|
578 sizeof (PK11_CIPHER_STATE), |
|
579 NULL, |
|
580 NULL, |
|
581 NULL |
|
582 }; |
|
583 |
|
584 static const EVP_CIPHER pk11_aes_256_ecb = |
|
585 { |
|
586 NID_aes_256_ecb, |
|
587 16, 32, 0, |
|
588 EVP_CIPH_ECB_MODE, |
|
589 pk11_cipher_init, |
|
590 pk11_cipher_do_cipher, |
|
591 pk11_cipher_cleanup, |
|
592 sizeof (PK11_CIPHER_STATE), |
|
593 NULL, |
|
594 NULL, |
|
595 NULL |
|
596 }; |
|
597 |
|
598 static EVP_CIPHER pk11_aes_128_ctr = |
|
599 { |
|
600 NID_aes_128_ctr, |
|
601 16, 16, 16, |
|
602 EVP_CIPH_CTR_MODE, |
|
603 pk11_cipher_init, |
|
604 pk11_cipher_do_cipher, |
|
605 pk11_cipher_cleanup, |
|
606 sizeof (PK11_CIPHER_STATE), |
|
607 EVP_CIPHER_set_asn1_iv, |
|
608 EVP_CIPHER_get_asn1_iv, |
|
609 NULL |
|
610 }; |
|
611 |
|
612 static EVP_CIPHER pk11_aes_192_ctr = |
|
613 { |
|
614 NID_aes_192_ctr, |
|
615 16, 24, 16, |
|
616 EVP_CIPH_CTR_MODE, |
|
617 pk11_cipher_init, |
|
618 pk11_cipher_do_cipher, |
|
619 pk11_cipher_cleanup, |
|
620 sizeof (PK11_CIPHER_STATE), |
|
621 EVP_CIPHER_set_asn1_iv, |
|
622 EVP_CIPHER_get_asn1_iv, |
|
623 NULL |
|
624 }; |
|
625 |
|
626 static EVP_CIPHER pk11_aes_256_ctr = |
|
627 { |
|
628 NID_aes_256_ctr, |
|
629 16, 32, 16, |
|
630 EVP_CIPH_CTR_MODE, |
|
631 pk11_cipher_init, |
|
632 pk11_cipher_do_cipher, |
|
633 pk11_cipher_cleanup, |
|
634 sizeof (PK11_CIPHER_STATE), |
|
635 EVP_CIPHER_set_asn1_iv, |
|
636 EVP_CIPHER_get_asn1_iv, |
|
637 NULL |
|
638 }; |
|
639 |
|
640 static const EVP_CIPHER pk11_bf_cbc = |
|
641 { |
|
642 NID_bf_cbc, |
|
643 8, 16, 8, |
|
644 EVP_CIPH_VARIABLE_LENGTH | EVP_CIPH_CBC_MODE, |
|
645 pk11_cipher_init, |
|
646 pk11_cipher_do_cipher, |
|
647 pk11_cipher_cleanup, |
|
648 sizeof (PK11_CIPHER_STATE), |
|
649 EVP_CIPHER_set_asn1_iv, |
|
650 EVP_CIPHER_get_asn1_iv, |
|
651 NULL |
|
652 }; |
|
653 |
|
654 static const EVP_CIPHER pk11_rc4 = |
|
655 { |
|
656 NID_rc4, |
|
657 1, 16, 0, |
|
658 EVP_CIPH_VARIABLE_LENGTH, |
|
659 pk11_cipher_init, |
|
660 pk11_cipher_do_cipher, |
|
661 pk11_cipher_cleanup, |
|
662 sizeof (PK11_CIPHER_STATE), |
|
663 NULL, |
|
664 NULL, |
|
665 NULL |
|
666 }; |
|
667 |
|
668 static const EVP_MD pk11_md5 = |
|
669 { |
|
670 NID_md5, |
|
671 NID_md5WithRSAEncryption, |
|
672 MD5_DIGEST_LENGTH, |
|
673 0, |
|
674 pk11_digest_init, |
|
675 pk11_digest_update, |
|
676 pk11_digest_final, |
|
677 pk11_digest_copy, |
|
678 pk11_digest_cleanup, |
|
679 EVP_PKEY_RSA_method, |
|
680 MD5_CBLOCK, |
|
681 sizeof (PK11_CIPHER_STATE), |
|
682 }; |
|
683 |
|
684 static const EVP_MD pk11_sha1 = |
|
685 { |
|
686 NID_sha1, |
|
687 NID_sha1WithRSAEncryption, |
|
688 SHA_DIGEST_LENGTH, |
|
689 EVP_MD_FLAG_PKEY_METHOD_SIGNATURE|EVP_MD_FLAG_DIGALGID_ABSENT, |
|
690 pk11_digest_init, |
|
691 pk11_digest_update, |
|
692 pk11_digest_final, |
|
693 pk11_digest_copy, |
|
694 pk11_digest_cleanup, |
|
695 EVP_PKEY_RSA_method, |
|
696 SHA_CBLOCK, |
|
697 sizeof (PK11_CIPHER_STATE), |
|
698 }; |
|
699 |
|
700 static const EVP_MD pk11_sha224 = |
|
701 { |
|
702 NID_sha224, |
|
703 NID_sha224WithRSAEncryption, |
|
704 SHA224_DIGEST_LENGTH, |
|
705 EVP_MD_FLAG_PKEY_METHOD_SIGNATURE|EVP_MD_FLAG_DIGALGID_ABSENT, |
|
706 pk11_digest_init, |
|
707 pk11_digest_update, |
|
708 pk11_digest_final, |
|
709 pk11_digest_copy, |
|
710 pk11_digest_cleanup, |
|
711 EVP_PKEY_RSA_method, |
|
712 /* SHA-224 uses the same cblock size as SHA-256 */ |
|
713 SHA256_CBLOCK, |
|
714 sizeof (PK11_CIPHER_STATE), |
|
715 }; |
|
716 |
|
717 static const EVP_MD pk11_sha256 = |
|
718 { |
|
719 NID_sha256, |
|
720 NID_sha256WithRSAEncryption, |
|
721 SHA256_DIGEST_LENGTH, |
|
722 EVP_MD_FLAG_PKEY_METHOD_SIGNATURE|EVP_MD_FLAG_DIGALGID_ABSENT, |
|
723 pk11_digest_init, |
|
724 pk11_digest_update, |
|
725 pk11_digest_final, |
|
726 pk11_digest_copy, |
|
727 pk11_digest_cleanup, |
|
728 EVP_PKEY_RSA_method, |
|
729 SHA256_CBLOCK, |
|
730 sizeof (PK11_CIPHER_STATE), |
|
731 }; |
|
732 |
|
733 static const EVP_MD pk11_sha384 = |
|
734 { |
|
735 NID_sha384, |
|
736 NID_sha384WithRSAEncryption, |
|
737 SHA384_DIGEST_LENGTH, |
|
738 EVP_MD_FLAG_PKEY_METHOD_SIGNATURE|EVP_MD_FLAG_DIGALGID_ABSENT, |
|
739 pk11_digest_init, |
|
740 pk11_digest_update, |
|
741 pk11_digest_final, |
|
742 pk11_digest_copy, |
|
743 pk11_digest_cleanup, |
|
744 EVP_PKEY_RSA_method, |
|
745 /* SHA-384 uses the same cblock size as SHA-512 */ |
|
746 SHA512_CBLOCK, |
|
747 sizeof (PK11_CIPHER_STATE), |
|
748 }; |
|
749 |
|
750 static const EVP_MD pk11_sha512 = |
|
751 { |
|
752 NID_sha512, |
|
753 NID_sha512WithRSAEncryption, |
|
754 SHA512_DIGEST_LENGTH, |
|
755 EVP_MD_FLAG_PKEY_METHOD_SIGNATURE|EVP_MD_FLAG_DIGALGID_ABSENT, |
|
756 pk11_digest_init, |
|
757 pk11_digest_update, |
|
758 pk11_digest_final, |
|
759 pk11_digest_copy, |
|
760 pk11_digest_cleanup, |
|
761 EVP_PKEY_RSA_method, |
|
762 SHA512_CBLOCK, |
|
763 sizeof (PK11_CIPHER_STATE), |
|
764 }; |
|
765 |
|
766 /* |
|
767 * Initialization function. Sets up various PKCS#11 library components. |
|
768 * The definitions for control commands specific to this engine |
|
769 */ |
|
770 #define PK11_CMD_SO_PATH ENGINE_CMD_BASE |
|
771 static const ENGINE_CMD_DEFN pk11_cmd_defns[] = |
|
772 { |
|
773 { |
|
774 PK11_CMD_SO_PATH, |
|
775 "SO_PATH", |
|
776 "Specifies the path to the 'pkcs#11' shared library", |
|
777 ENGINE_CMD_FLAG_STRING |
|
778 }, |
|
779 {0, NULL, NULL, 0} |
|
780 }; |
|
781 |
|
782 |
|
783 static RAND_METHOD pk11_random = |
|
784 { |
|
785 pk11_rand_seed, |
|
786 pk11_rand_bytes, |
|
787 pk11_rand_cleanup, |
|
788 pk11_rand_add, |
|
789 pk11_rand_bytes, |
|
790 pk11_rand_status |
|
791 }; |
|
792 |
|
793 |
|
794 /* Constants used when creating the ENGINE */ |
|
795 static const char *engine_pk11_id = "pkcs11"; |
|
796 static const char *engine_pk11_name = "PKCS #11 engine support"; |
|
797 |
|
798 CK_FUNCTION_LIST_PTR pFuncList = NULL; |
|
799 static const char PK11_GET_FUNCTION_LIST[] = "C_GetFunctionList"; |
|
800 |
|
801 /* |
|
802 * This is a static string constant for the DSO file name and the function |
|
803 * symbol names to bind to. We set it in the Configure script based on whether |
|
804 * this is 32 or 64 bit build. |
|
805 */ |
|
806 static const char def_PK11_LIBNAME[] = PK11_LIB_LOCATION; |
|
807 |
|
808 /* Needed in e_pk11_pub.c as well so that's why it is not static. */ |
|
809 CK_SLOT_ID pubkey_SLOTID = 0; |
|
810 static CK_SLOT_ID rand_SLOTID = 0; |
|
811 static CK_SLOT_ID SLOTID = 0; |
|
812 static CK_BBOOL pk11_library_initialized = CK_FALSE; |
|
813 static CK_BBOOL pk11_atfork_initialized = CK_FALSE; |
|
814 static int pk11_pid = 0; |
|
815 static ENGINE* pk11_engine = NULL; |
|
816 |
|
817 static DSO *pk11_dso = NULL; |
|
818 |
|
819 /* allocate and initialize all locks used by the engine itself */ |
|
820 static int pk11_init_all_locks(void) |
|
821 { |
|
822 int type; |
|
823 |
|
824 #ifndef OPENSSL_NO_RSA |
|
825 find_lock[OP_RSA] = OPENSSL_malloc(sizeof (pthread_mutex_t)); |
|
826 if (find_lock[OP_RSA] == NULL) |
|
827 goto malloc_err; |
|
828 (void) pthread_mutex_init(find_lock[OP_RSA], NULL); |
|
829 #endif /* OPENSSL_NO_RSA */ |
|
830 |
|
831 if ((uri_lock = OPENSSL_malloc(sizeof (pthread_mutex_t))) == NULL) |
|
832 goto malloc_err; |
|
833 (void) pthread_mutex_init(uri_lock, NULL); |
|
834 |
|
835 #ifndef OPENSSL_NO_DSA |
|
836 find_lock[OP_DSA] = OPENSSL_malloc(sizeof (pthread_mutex_t)); |
|
837 if (find_lock[OP_DSA] == NULL) |
|
838 goto malloc_err; |
|
839 (void) pthread_mutex_init(find_lock[OP_DSA], NULL); |
|
840 #endif /* OPENSSL_NO_DSA */ |
|
841 |
|
842 #ifndef OPENSSL_NO_DH |
|
843 find_lock[OP_DH] = OPENSSL_malloc(sizeof (pthread_mutex_t)); |
|
844 if (find_lock[OP_DH] == NULL) |
|
845 goto malloc_err; |
|
846 (void) pthread_mutex_init(find_lock[OP_DH], NULL); |
|
847 #endif /* OPENSSL_NO_DH */ |
|
848 |
|
849 for (type = 0; type < OP_MAX; type++) |
|
850 { |
|
851 session_cache[type].lock = |
|
852 OPENSSL_malloc(sizeof (pthread_mutex_t)); |
|
853 if (session_cache[type].lock == NULL) |
|
854 goto malloc_err; |
|
855 (void) pthread_mutex_init(session_cache[type].lock, NULL); |
|
856 } |
|
857 |
|
858 return (1); |
|
859 |
|
860 malloc_err: |
|
861 pk11_free_all_locks(); |
|
862 PK11err(PK11_F_INIT_ALL_LOCKS, PK11_R_MALLOC_FAILURE); |
|
863 return (0); |
|
864 } |
|
865 |
|
866 static void pk11_free_all_locks(void) |
|
867 { |
|
868 int type; |
|
869 |
|
870 #ifndef OPENSSL_NO_RSA |
|
871 if (find_lock[OP_RSA] != NULL) |
|
872 { |
|
873 (void) pthread_mutex_destroy(find_lock[OP_RSA]); |
|
874 OPENSSL_free(find_lock[OP_RSA]); |
|
875 find_lock[OP_RSA] = NULL; |
|
876 } |
|
877 #endif /* OPENSSL_NO_RSA */ |
|
878 #ifndef OPENSSL_NO_DSA |
|
879 if (find_lock[OP_DSA] != NULL) |
|
880 { |
|
881 (void) pthread_mutex_destroy(find_lock[OP_DSA]); |
|
882 OPENSSL_free(find_lock[OP_DSA]); |
|
883 find_lock[OP_DSA] = NULL; |
|
884 } |
|
885 #endif /* OPENSSL_NO_DSA */ |
|
886 #ifndef OPENSSL_NO_DH |
|
887 if (find_lock[OP_DH] != NULL) |
|
888 { |
|
889 (void) pthread_mutex_destroy(find_lock[OP_DH]); |
|
890 OPENSSL_free(find_lock[OP_DH]); |
|
891 find_lock[OP_DH] = NULL; |
|
892 } |
|
893 #endif /* OPENSSL_NO_DH */ |
|
894 |
|
895 for (type = 0; type < OP_MAX; type++) |
|
896 { |
|
897 if (session_cache[type].lock != NULL) |
|
898 { |
|
899 (void) pthread_mutex_destroy(session_cache[type].lock); |
|
900 OPENSSL_free(session_cache[type].lock); |
|
901 session_cache[type].lock = NULL; |
|
902 } |
|
903 } |
|
904 /* Free uri_lock */ |
|
905 (void) pthread_mutex_destroy(uri_lock); |
|
906 OPENSSL_free(uri_lock); |
|
907 uri_lock = NULL; |
|
908 } |
|
909 |
|
910 /* |
|
911 * This internal function is used by ENGINE_pk11() and "dynamic" ENGINE support. |
|
912 */ |
|
913 static int bind_pk11(ENGINE *e) |
|
914 { |
|
915 #ifndef OPENSSL_NO_RSA |
|
916 const RSA_METHOD *rsa = NULL; |
|
917 RSA_METHOD *pk11_rsa = PK11_RSA(); |
|
918 #endif /* OPENSSL_NO_RSA */ |
|
919 if (!pk11_library_initialized) |
|
920 if (!pk11_library_init(e)) |
|
921 return (0); |
|
922 |
|
923 if (!ENGINE_set_id(e, engine_pk11_id) || |
|
924 !ENGINE_set_name(e, engine_pk11_name) || |
|
925 !ENGINE_set_ciphers(e, pk11_engine_ciphers) || |
|
926 !ENGINE_set_digests(e, pk11_engine_digests)) |
|
927 return (0); |
|
928 |
|
929 if (!ENGINE_set_pkey_meths(e, pk11_engine_pkey_methods)) |
|
930 return (0); |
|
931 |
|
932 #ifndef OPENSSL_NO_RSA |
|
933 if (pk11_have_rsa == CK_TRUE) |
|
934 { |
|
935 if (!ENGINE_set_RSA(e, PK11_RSA()) || |
|
936 !ENGINE_set_load_privkey_function(e, pk11_load_privkey) || |
|
937 !ENGINE_set_load_pubkey_function(e, pk11_load_pubkey)) |
|
938 return (0); |
|
939 DEBUG_SLOT_SEL("%s: registered RSA\n", PK11_DBG); |
|
940 } |
|
941 #endif /* OPENSSL_NO_RSA */ |
|
942 #ifndef OPENSSL_NO_DSA |
|
943 if (pk11_have_dsa == CK_TRUE) |
|
944 { |
|
945 if (!ENGINE_set_DSA(e, PK11_DSA())) |
|
946 return (0); |
|
947 DEBUG_SLOT_SEL("%s: registered DSA\n", PK11_DBG); |
|
948 } |
|
949 #endif /* OPENSSL_NO_DSA */ |
|
950 #ifndef OPENSSL_NO_DH |
|
951 if (pk11_have_dh == CK_TRUE) |
|
952 { |
|
953 if (!ENGINE_set_DH(e, PK11_DH())) |
|
954 return (0); |
|
955 DEBUG_SLOT_SEL("%s: registered DH\n", PK11_DBG); |
|
956 } |
|
957 #endif /* OPENSSL_NO_DH */ |
|
958 if (pk11_have_random) |
|
959 { |
|
960 if (!ENGINE_set_RAND(e, &pk11_random)) |
|
961 return (0); |
|
962 DEBUG_SLOT_SEL("%s: registered random\n", PK11_DBG); |
|
963 } |
|
964 if (!ENGINE_set_init_function(e, pk11_init) || |
|
965 !ENGINE_set_destroy_function(e, pk11_destroy) || |
|
966 !ENGINE_set_finish_function(e, pk11_finish) || |
|
967 !ENGINE_set_ctrl_function(e, pk11_ctrl) || |
|
968 !ENGINE_set_cmd_defns(e, pk11_cmd_defns)) |
|
969 return (0); |
|
970 |
|
971 /* |
|
972 * Apache calls OpenSSL function RSA_blinding_on() once during startup |
|
973 * which in turn calls bn_mod_exp. Since we do not implement bn_mod_exp |
|
974 * here, we wire it back to the OpenSSL software implementation. |
|
975 * Since it is used only once, performance is not a concern. |
|
976 */ |
|
977 #ifndef OPENSSL_NO_RSA |
|
978 rsa = RSA_PKCS1_SSLeay(); |
|
979 pk11_rsa->rsa_mod_exp = rsa->rsa_mod_exp; |
|
980 pk11_rsa->bn_mod_exp = rsa->bn_mod_exp; |
|
981 #endif /* OPENSSL_NO_RSA */ |
|
982 |
|
983 /* Ensure the pk11 error handling is set up */ |
|
984 ERR_load_pk11_strings(); |
|
985 |
|
986 return (1); |
|
987 } |
|
988 |
|
989 static int bind_helper(ENGINE *e, const char *id) |
|
990 { |
|
991 if (id && (strcmp(id, engine_pk11_id) != 0)) |
|
992 return (0); |
|
993 |
|
994 if (!bind_pk11(e)) |
|
995 return (0); |
|
996 |
|
997 return (1); |
|
998 } |
|
999 |
|
1000 IMPLEMENT_DYNAMIC_CHECK_FN() |
|
1001 IMPLEMENT_DYNAMIC_BIND_FN(bind_helper) |
|
1002 |
|
1003 /* |
|
1004 * These are the static string constants for the DSO file name and |
|
1005 * the function symbol names to bind to. |
|
1006 */ |
|
1007 static const char *PK11_LIBNAME = NULL; |
|
1008 |
|
1009 static const char *get_PK11_LIBNAME(void) |
|
1010 { |
|
1011 if (PK11_LIBNAME) |
|
1012 return (PK11_LIBNAME); |
|
1013 |
|
1014 return (def_PK11_LIBNAME); |
|
1015 } |
|
1016 |
|
1017 static void free_PK11_LIBNAME(void) |
|
1018 { |
|
1019 if (PK11_LIBNAME) |
|
1020 OPENSSL_free((void*)PK11_LIBNAME); |
|
1021 |
|
1022 PK11_LIBNAME = NULL; |
|
1023 } |
|
1024 |
|
1025 static long set_PK11_LIBNAME(const char *name) |
|
1026 { |
|
1027 free_PK11_LIBNAME(); |
|
1028 |
|
1029 return ((PK11_LIBNAME = BUF_strdup(name)) != NULL ? 1 : 0); |
|
1030 } |
|
1031 |
|
1032 /* acquire all engine specific mutexes before fork */ |
|
1033 static void pk11_fork_prepare(void) |
|
1034 { |
|
1035 int i; |
|
1036 |
|
1037 if (!pk11_library_initialized) |
|
1038 return; |
|
1039 |
|
1040 LOCK_OBJSTORE(OP_RSA); |
|
1041 LOCK_OBJSTORE(OP_DSA); |
|
1042 LOCK_OBJSTORE(OP_DH); |
|
1043 (void) pthread_mutex_lock(uri_lock); |
|
1044 for (i = 0; i < OP_MAX; i++) |
|
1045 { |
|
1046 (void) pthread_mutex_lock(session_cache[i].lock); |
|
1047 } |
|
1048 } |
|
1049 |
|
1050 /* release all engine specific mutexes */ |
|
1051 static void pk11_fork_parent(void) |
|
1052 { |
|
1053 int i; |
|
1054 |
|
1055 if (!pk11_library_initialized) |
|
1056 return; |
|
1057 |
|
1058 for (i = OP_MAX - 1; i >= 0; i--) |
|
1059 { |
|
1060 (void) pthread_mutex_unlock(session_cache[i].lock); |
|
1061 } |
|
1062 UNLOCK_OBJSTORE(OP_DH); |
|
1063 UNLOCK_OBJSTORE(OP_DSA); |
|
1064 UNLOCK_OBJSTORE(OP_RSA); |
|
1065 (void) pthread_mutex_unlock(uri_lock); |
|
1066 } |
|
1067 |
|
1068 /* |
|
1069 * same situation as in parent - we need to unlock all locks to make them |
|
1070 * accessible to all threads. |
|
1071 */ |
|
1072 static void pk11_fork_child(void) |
|
1073 { |
|
1074 int i; |
|
1075 |
|
1076 if (!pk11_library_initialized) |
|
1077 return; |
|
1078 |
|
1079 /* invalidate the global session */ |
|
1080 global_session = CK_INVALID_HANDLE; |
|
1081 |
|
1082 for (i = OP_MAX - 1; i >= 0; i--) |
|
1083 { |
|
1084 (void) pthread_mutex_unlock(session_cache[i].lock); |
|
1085 } |
|
1086 UNLOCK_OBJSTORE(OP_DH); |
|
1087 UNLOCK_OBJSTORE(OP_DSA); |
|
1088 UNLOCK_OBJSTORE(OP_RSA); |
|
1089 (void) pthread_mutex_unlock(uri_lock); |
|
1090 } |
|
1091 |
|
1092 /* Initialization function for the pk11 engine */ |
|
1093 static int pk11_init(ENGINE *e) |
|
1094 { |
|
1095 return (pk11_library_init(e)); |
|
1096 } |
|
1097 |
|
1098 /* |
|
1099 * Helper function that unsets reference to current engine (pk11_engine = NULL). |
|
1100 * |
|
1101 * Use of local variable only seems clumsy, it needs to be this way! |
|
1102 * This is to prevent double free in the unlucky scenario: |
|
1103 * ENGINE_free calls pk11_destroy calls pk11_finish calls ENGINE_free |
|
1104 * Setting pk11_engine to NULL prior to ENGINE_free() avoids this. |
|
1105 */ |
|
1106 static void pk11_engine_free() |
|
1107 { |
|
1108 ENGINE* old_engine = pk11_engine; |
|
1109 |
|
1110 if (old_engine) |
|
1111 { |
|
1112 pk11_engine = NULL; |
|
1113 } |
|
1114 } |
|
1115 |
|
1116 /* |
|
1117 * Initialization function. Sets up various PKCS#11 library components. |
|
1118 * It selects a slot based on predefined critiera. In the process, it also |
|
1119 * count how many ciphers and digests to support. Since the cipher and |
|
1120 * digest information is needed when setting default engine, this function |
|
1121 * needs to be called before calling ENGINE_set_default. |
|
1122 */ |
|
1123 /* ARGSUSED */ |
|
1124 static int pk11_library_init(ENGINE *e) |
|
1125 { |
|
1126 CK_C_GetFunctionList p; |
|
1127 CK_RV rv = CKR_OK; |
|
1128 CK_INFO info; |
|
1129 CK_ULONG ul_state_len; |
|
1130 int any_slot_found; |
|
1131 int i; |
|
1132 |
|
1133 if (e != pk11_engine) |
|
1134 { |
|
1135 pk11_engine_free(); |
|
1136 pk11_engine = e; |
|
1137 } |
|
1138 |
|
1139 /* |
|
1140 * pk11_library_initialized is set to 0 in pk11_finish() which is called |
|
1141 * from ENGINE_finish(). However, if there is still at least one |
|
1142 * existing functional reference to the engine (see engine(3) for more |
|
1143 * information), pk11_finish() is skipped. For example, this can happen |
|
1144 * if an application forgets to clear one cipher context. In case of a |
|
1145 * fork() when the application is finishing the engine so that it can be |
|
1146 * reinitialized in the child, forgotten functional reference causes |
|
1147 * pk11_library_initialized to stay 1. In that case we need the PID |
|
1148 * check so that we properly initialize the engine again. |
|
1149 */ |
|
1150 if (pk11_library_initialized) |
|
1151 { |
|
1152 if (pk11_pid == getpid()) |
|
1153 { |
|
1154 return (1); |
|
1155 } |
|
1156 else |
|
1157 { |
|
1158 global_session = CK_INVALID_HANDLE; |
|
1159 /* |
|
1160 * free the locks first to prevent memory leak in case |
|
1161 * the application calls fork() without finishing the |
|
1162 * engine first. |
|
1163 */ |
|
1164 pk11_free_all_locks(); |
|
1165 } |
|
1166 } |
|
1167 |
|
1168 |
|
1169 /* |
|
1170 * If initialization of the locks fails pk11_init_all_locks() |
|
1171 * will do the cleanup. |
|
1172 */ |
|
1173 if (!pk11_init_all_locks()) |
|
1174 goto err; |
|
1175 for (i = 0; i < OP_MAX; i++) |
|
1176 session_cache[i].head = NULL; |
|
1177 /* |
|
1178 * Initialize active lists. We only use active lists |
|
1179 * for asymmetric ciphers. |
|
1180 */ |
|
1181 for (i = 0; i < OP_MAX; i++) |
|
1182 active_list[i] = NULL; |
|
1183 |
|
1184 /* Attempt to load PKCS#11 library. */ |
|
1185 if (!pk11_dso) |
|
1186 { |
|
1187 pk11_dso = DSO_load(NULL, get_PK11_LIBNAME(), NULL, 0); |
|
1188 if (pk11_dso == NULL) |
|
1189 { |
|
1190 PK11err(PK11_F_LOAD, PK11_R_DSO_FAILURE); |
|
1191 goto err; |
|
1192 } |
|
1193 } |
|
1194 |
|
1195 #ifdef SOLARIS_HW_SLOT_SELECTION |
|
1196 if (check_hw_mechanisms() == 0) |
|
1197 goto err; |
|
1198 #endif /* SOLARIS_HW_SLOT_SELECTION */ |
|
1199 |
|
1200 /* get the C_GetFunctionList function from the loaded library */ |
|
1201 p = (CK_C_GetFunctionList)DSO_bind_func(pk11_dso, |
|
1202 PK11_GET_FUNCTION_LIST); |
|
1203 if (!p) |
|
1204 { |
|
1205 PK11err(PK11_F_LIBRARY_INIT, PK11_R_DSO_FAILURE); |
|
1206 goto err; |
|
1207 } |
|
1208 |
|
1209 /* get the full function list from the loaded library */ |
|
1210 rv = p(&pFuncList); |
|
1211 if (rv != CKR_OK) |
|
1212 { |
|
1213 PK11err_add_data(PK11_F_LIBRARY_INIT, PK11_R_DSO_FAILURE, rv); |
|
1214 goto err; |
|
1215 } |
|
1216 |
|
1217 rv = pFuncList->C_Initialize(NULL_PTR); |
|
1218 if ((rv != CKR_OK) && (rv != CKR_CRYPTOKI_ALREADY_INITIALIZED)) |
|
1219 { |
|
1220 PK11err_add_data(PK11_F_LIBRARY_INIT, PK11_R_INITIALIZE, rv); |
|
1221 goto err; |
|
1222 } |
|
1223 |
|
1224 rv = pFuncList->C_GetInfo(&info); |
|
1225 if (rv != CKR_OK) |
|
1226 { |
|
1227 PK11err_add_data(PK11_F_LIBRARY_INIT, PK11_R_GETINFO, rv); |
|
1228 goto err; |
|
1229 } |
|
1230 |
|
1231 if (pk11_choose_slots(&any_slot_found) == 0) |
|
1232 goto err; |
|
1233 |
|
1234 /* |
|
1235 * The library we use, set in def_PK11_LIBNAME, may not offer any |
|
1236 * slot(s). In that case, we must not proceed but we must not return an |
|
1237 * error. The reason is that applications that try to set up the PKCS#11 |
|
1238 * engine don't exit on error during the engine initialization just |
|
1239 * because no slot was present. |
|
1240 */ |
|
1241 if (any_slot_found == 0) |
|
1242 return (1); |
|
1243 |
|
1244 if (global_session == CK_INVALID_HANDLE) |
|
1245 { |
|
1246 /* Open the global_session for the new process */ |
|
1247 rv = pFuncList->C_OpenSession(SLOTID, CKF_SERIAL_SESSION, |
|
1248 NULL_PTR, NULL_PTR, &global_session); |
|
1249 if (rv != CKR_OK) |
|
1250 { |
|
1251 PK11err_add_data(PK11_F_LIBRARY_INIT, |
|
1252 PK11_R_OPENSESSION, rv); |
|
1253 goto err; |
|
1254 } |
|
1255 } |
|
1256 |
|
1257 /* |
|
1258 * Disable digest if C_GetOperationState is not supported since |
|
1259 * this function is required by OpenSSL digest copy function |
|
1260 */ |
|
1261 if (pFuncList->C_GetOperationState(global_session, NULL, &ul_state_len) |
|
1262 == CKR_FUNCTION_NOT_SUPPORTED) |
|
1263 { |
|
1264 DEBUG_SLOT_SEL("%s: C_GetOperationState() not supported, " |
|
1265 "setting digest_count to 0\n", PK11_DBG); |
|
1266 digest_count = 0; |
|
1267 } |
|
1268 |
|
1269 pk11_library_initialized = CK_TRUE; |
|
1270 pk11_pid = getpid(); |
|
1271 |
|
1272 if (!pk11_atfork_initialized) |
|
1273 { |
|
1274 if (pthread_atfork(pk11_fork_prepare, pk11_fork_parent, |
|
1275 pk11_fork_child) != 0) |
|
1276 { |
|
1277 PK11err(PK11_F_LIBRARY_INIT, PK11_R_ATFORK_FAILED); |
|
1278 goto err; |
|
1279 } |
|
1280 pk11_atfork_initialized = CK_TRUE; |
|
1281 } |
|
1282 |
|
1283 return (1); |
|
1284 |
|
1285 err: |
|
1286 return (0); |
|
1287 } |
|
1288 |
|
1289 /* Destructor (complements the "ENGINE_pk11()" constructor) */ |
|
1290 /* ARGSUSED */ |
|
1291 static int pk11_destroy(ENGINE *e) |
|
1292 { |
|
1293 int rtn = 1; |
|
1294 |
|
1295 free_PK11_LIBNAME(); |
|
1296 ERR_unload_pk11_strings(); |
|
1297 if (pk11_library_initialized == CK_TRUE) |
|
1298 rtn = pk11_finish(e); |
|
1299 |
|
1300 return (rtn); |
|
1301 } |
|
1302 |
|
1303 /* |
|
1304 * Termination function to clean up the session, the token, and the pk11 |
|
1305 * library. |
|
1306 */ |
|
1307 /* ARGSUSED */ |
|
1308 static int pk11_finish(ENGINE *e) |
|
1309 { |
|
1310 int i; |
|
1311 |
|
1312 /* |
|
1313 * Make sure, right engine instance is being destroyed. |
|
1314 * Engine e may be the wrong instance if |
|
1315 * 1) either someone calls ENGINE_load_pk11 twice |
|
1316 * 2) or last ref. to an already finished engine is being destroyed |
|
1317 */ |
|
1318 if (e != pk11_engine) |
|
1319 goto err; |
|
1320 |
|
1321 if (pk11_dso == NULL) |
|
1322 { |
|
1323 PK11err(PK11_F_FINISH, PK11_R_NOT_LOADED); |
|
1324 goto err; |
|
1325 } |
|
1326 |
|
1327 OPENSSL_assert(pFuncList != NULL); |
|
1328 |
|
1329 if (pk11_free_all_sessions() == 0) |
|
1330 goto err; |
|
1331 |
|
1332 /* free all active lists */ |
|
1333 for (i = 0; i < OP_MAX; i++) |
|
1334 pk11_free_active_list(i); |
|
1335 |
|
1336 /* Global session is not present when there are no slots. */ |
|
1337 if (global_session != CK_INVALID_HANDLE) |
|
1338 { |
|
1339 pFuncList->C_CloseSession(global_session); |
|
1340 global_session = CK_INVALID_HANDLE; |
|
1341 } |
|
1342 |
|
1343 /* |
|
1344 * Since we are part of a library (libcrypto.so), calling this function |
|
1345 * may have side-effects. |
|
1346 */ |
|
1347 #if 0 |
|
1348 pFuncList->C_Finalize(NULL); |
|
1349 #endif |
|
1350 if (!DSO_free(pk11_dso)) |
|
1351 { |
|
1352 PK11err(PK11_F_FINISH, PK11_R_DSO_FAILURE); |
|
1353 goto err; |
|
1354 } |
|
1355 pk11_dso = NULL; |
|
1356 pFuncList = NULL; |
|
1357 pk11_library_initialized = CK_FALSE; |
|
1358 pk11_pid = 0; |
|
1359 pk11_engine_free(); |
|
1360 /* |
|
1361 * There is no way how to unregister atfork handlers (other than |
|
1362 * unloading the library) so we just free the locks. For this reason |
|
1363 * the atfork handlers check if the engine is initialized and bail out |
|
1364 * immediately if not. This is necessary in case a process finishes |
|
1365 * the engine before calling fork(). |
|
1366 */ |
|
1367 pk11_free_all_locks(); |
|
1368 |
|
1369 return (1); |
|
1370 |
|
1371 err: |
|
1372 return (0); |
|
1373 } |
|
1374 |
|
1375 /* Standard engine interface function to set the dynamic library path */ |
|
1376 /* ARGSUSED */ |
|
1377 static int pk11_ctrl(ENGINE *e, int cmd, long i, void *p, void (*f)()) |
|
1378 { |
|
1379 int initialized = ((pk11_dso == NULL) ? 0 : 1); |
|
1380 |
|
1381 switch (cmd) |
|
1382 { |
|
1383 case PK11_CMD_SO_PATH: |
|
1384 if (p == NULL) |
|
1385 { |
|
1386 PK11err(PK11_F_CTRL, ERR_R_PASSED_NULL_PARAMETER); |
|
1387 return (0); |
|
1388 } |
|
1389 |
|
1390 if (initialized) |
|
1391 { |
|
1392 PK11err(PK11_F_CTRL, PK11_R_ALREADY_LOADED); |
|
1393 return (0); |
|
1394 } |
|
1395 |
|
1396 return (set_PK11_LIBNAME((const char *)p)); |
|
1397 default: |
|
1398 break; |
|
1399 } |
|
1400 |
|
1401 PK11err(PK11_F_CTRL, PK11_R_CTRL_COMMAND_NOT_IMPLEMENTED); |
|
1402 |
|
1403 return (0); |
|
1404 } |
|
1405 |
|
1406 |
|
1407 /* Required function by the engine random interface. It does nothing here */ |
|
1408 static void pk11_rand_cleanup(void) |
|
1409 { |
|
1410 return; |
|
1411 } |
|
1412 |
|
1413 /* ARGSUSED */ |
|
1414 static void pk11_rand_add(const void *buf, int num, double add) |
|
1415 { |
|
1416 PK11_SESSION *sp; |
|
1417 |
|
1418 if ((sp = pk11_get_session(OP_RAND)) == NULL) |
|
1419 return; |
|
1420 |
|
1421 /* |
|
1422 * Ignore any errors (e.g. CKR_RANDOM_SEED_NOT_SUPPORTED) since |
|
1423 * the calling functions do not care anyway |
|
1424 */ |
|
1425 pFuncList->C_SeedRandom(sp->session, (unsigned char *) buf, num); |
|
1426 pk11_return_session(sp, OP_RAND); |
|
1427 |
|
1428 return; |
|
1429 } |
|
1430 |
|
1431 static void pk11_rand_seed(const void *buf, int num) |
|
1432 { |
|
1433 pk11_rand_add(buf, num, 0); |
|
1434 } |
|
1435 |
|
1436 static int pk11_rand_bytes(unsigned char *buf, int num) |
|
1437 { |
|
1438 CK_RV rv; |
|
1439 PK11_SESSION *sp; |
|
1440 |
|
1441 if ((sp = pk11_get_session(OP_RAND)) == NULL) |
|
1442 return (0); |
|
1443 |
|
1444 rv = pFuncList->C_GenerateRandom(sp->session, buf, num); |
|
1445 if (rv != CKR_OK) |
|
1446 { |
|
1447 PK11err_add_data(PK11_F_RAND_BYTES, PK11_R_GENERATERANDOM, rv); |
|
1448 pk11_return_session(sp, OP_RAND); |
|
1449 return (0); |
|
1450 } |
|
1451 |
|
1452 pk11_return_session(sp, OP_RAND); |
|
1453 return (1); |
|
1454 } |
|
1455 |
|
1456 /* Required function by the engine random interface. It does nothing here */ |
|
1457 static int pk11_rand_status(void) |
|
1458 { |
|
1459 return (1); |
|
1460 } |
|
1461 |
|
1462 /* Free all BIGNUM structures from PK11_SESSION. */ |
|
1463 static void pk11_free_nums(PK11_SESSION *sp, PK11_OPTYPE optype) |
|
1464 { |
|
1465 switch (optype) |
|
1466 { |
|
1467 #ifndef OPENSSL_NO_RSA |
|
1468 case OP_RSA: |
|
1469 if (sp->opdata_rsa_n_num != NULL) |
|
1470 { |
|
1471 BN_free(sp->opdata_rsa_n_num); |
|
1472 sp->opdata_rsa_n_num = NULL; |
|
1473 } |
|
1474 if (sp->opdata_rsa_e_num != NULL) |
|
1475 { |
|
1476 BN_free(sp->opdata_rsa_e_num); |
|
1477 sp->opdata_rsa_e_num = NULL; |
|
1478 } |
|
1479 if (sp->opdata_rsa_d_num != NULL) |
|
1480 { |
|
1481 BN_free(sp->opdata_rsa_d_num); |
|
1482 sp->opdata_rsa_d_num = NULL; |
|
1483 } |
|
1484 break; |
|
1485 #endif |
|
1486 #ifndef OPENSSL_NO_DSA |
|
1487 case OP_DSA: |
|
1488 if (sp->opdata_dsa_pub_num != NULL) |
|
1489 { |
|
1490 BN_free(sp->opdata_dsa_pub_num); |
|
1491 sp->opdata_dsa_pub_num = NULL; |
|
1492 } |
|
1493 if (sp->opdata_dsa_priv_num != NULL) |
|
1494 { |
|
1495 BN_free(sp->opdata_dsa_priv_num); |
|
1496 sp->opdata_dsa_priv_num = NULL; |
|
1497 } |
|
1498 break; |
|
1499 #endif |
|
1500 #ifndef OPENSSL_NO_DH |
|
1501 case OP_DH: |
|
1502 if (sp->opdata_dh_priv_num != NULL) |
|
1503 { |
|
1504 BN_free(sp->opdata_dh_priv_num); |
|
1505 sp->opdata_dh_priv_num = NULL; |
|
1506 } |
|
1507 break; |
|
1508 #endif |
|
1509 default: |
|
1510 break; |
|
1511 } |
|
1512 } |
|
1513 |
|
1514 /* |
|
1515 * Get new PK11_SESSION structure ready for use. Every process must have |
|
1516 * its own freelist of PK11_SESSION structures so handle fork() here |
|
1517 * by destroying the old and creating new freelist. |
|
1518 * The returned PK11_SESSION structure is disconnected from the freelist. |
|
1519 */ |
|
1520 PK11_SESSION * |
|
1521 pk11_get_session(PK11_OPTYPE optype) |
|
1522 { |
|
1523 PK11_SESSION *sp = NULL, *sp1, *freelist; |
|
1524 pthread_mutex_t *freelist_lock; |
|
1525 static pid_t pid = 0; |
|
1526 pid_t new_pid; |
|
1527 CK_RV rv; |
|
1528 |
|
1529 switch (optype) |
|
1530 { |
|
1531 case OP_RSA: |
|
1532 case OP_DSA: |
|
1533 case OP_DH: |
|
1534 case OP_RAND: |
|
1535 case OP_DIGEST: |
|
1536 case OP_CIPHER: |
|
1537 freelist_lock = session_cache[optype].lock; |
|
1538 break; |
|
1539 default: |
|
1540 PK11err(PK11_F_GET_SESSION, |
|
1541 PK11_R_INVALID_OPERATION_TYPE); |
|
1542 return (NULL); |
|
1543 } |
|
1544 (void) pthread_mutex_lock(freelist_lock); |
|
1545 |
|
1546 /* |
|
1547 * Will use it to find out if we forked. We cannot use the PID field in |
|
1548 * the session structure because we could get a newly allocated session |
|
1549 * here, with no PID information. |
|
1550 */ |
|
1551 if (pid == 0) |
|
1552 pid = getpid(); |
|
1553 |
|
1554 freelist = session_cache[optype].head; |
|
1555 sp = freelist; |
|
1556 |
|
1557 /* |
|
1558 * If the free list is empty, allocate new uninitialized (filled |
|
1559 * with zeroes) PK11_SESSION structure otherwise return first |
|
1560 * structure from the freelist. |
|
1561 */ |
|
1562 if (sp == NULL) |
|
1563 { |
|
1564 if ((sp = OPENSSL_malloc(sizeof (PK11_SESSION))) == NULL) |
|
1565 { |
|
1566 PK11err(PK11_F_GET_SESSION, |
|
1567 PK11_R_MALLOC_FAILURE); |
|
1568 goto err; |
|
1569 } |
|
1570 (void) memset(sp, 0, sizeof (PK11_SESSION)); |
|
1571 |
|
1572 /* |
|
1573 * It is a new session so it will look like a cache miss to the |
|
1574 * code below. So, we must not try to to destroy its members so |
|
1575 * mark them as unused. |
|
1576 */ |
|
1577 sp->opdata_rsa_priv_key = CK_INVALID_HANDLE; |
|
1578 sp->opdata_rsa_pub_key = CK_INVALID_HANDLE; |
|
1579 } |
|
1580 else |
|
1581 freelist = sp->next; |
|
1582 |
|
1583 /* |
|
1584 * Check whether we have forked. In that case, we must get rid of all |
|
1585 * inherited sessions and start allocating new ones. |
|
1586 */ |
|
1587 if (pid != (new_pid = getpid())) |
|
1588 { |
|
1589 pid = new_pid; |
|
1590 |
|
1591 /* |
|
1592 * We are a new process and thus need to free any inherited |
|
1593 * PK11_SESSION objects aside from the first session (sp) which |
|
1594 * is the only PK11_SESSION structure we will reuse (for the |
|
1595 * head of the list). |
|
1596 */ |
|
1597 while ((sp1 = freelist) != NULL) |
|
1598 { |
|
1599 freelist = sp1->next; |
|
1600 /* |
|
1601 * NOTE: we do not want to call pk11_free_all_sessions() |
|
1602 * here because it would close underlying PKCS#11 |
|
1603 * sessions and destroy all objects. |
|
1604 */ |
|
1605 pk11_free_nums(sp1, optype); |
|
1606 OPENSSL_free(sp1); |
|
1607 } |
|
1608 |
|
1609 /* we have to free the active list as well. */ |
|
1610 pk11_free_active_list(optype); |
|
1611 |
|
1612 /* Initialize the process */ |
|
1613 rv = pFuncList->C_Initialize(NULL_PTR); |
|
1614 if ((rv != CKR_OK) && (rv != CKR_CRYPTOKI_ALREADY_INITIALIZED)) |
|
1615 { |
|
1616 PK11err_add_data(PK11_F_GET_SESSION, PK11_R_INITIALIZE, |
|
1617 rv); |
|
1618 OPENSSL_free(sp); |
|
1619 sp = NULL; |
|
1620 goto err; |
|
1621 } |
|
1622 |
|
1623 /* |
|
1624 * Choose slot here since the slot table is different on this |
|
1625 * process. If we are here then we must have found at least one |
|
1626 * usable slot before so we don't need to check any_slot_found. |
|
1627 * See pk11_library_init()'s usage of this function for more |
|
1628 * information. |
|
1629 */ |
|
1630 #ifdef SOLARIS_HW_SLOT_SELECTION |
|
1631 if (check_hw_mechanisms() == 0) |
|
1632 goto err; |
|
1633 #endif /* SOLARIS_HW_SLOT_SELECTION */ |
|
1634 if (pk11_choose_slots(NULL) == 0) |
|
1635 goto err; |
|
1636 |
|
1637 /* Open the global_session for the new process */ |
|
1638 rv = pFuncList->C_OpenSession(SLOTID, CKF_SERIAL_SESSION, |
|
1639 NULL_PTR, NULL_PTR, &global_session); |
|
1640 if (rv != CKR_OK) |
|
1641 { |
|
1642 PK11err_add_data(PK11_F_GET_SESSION, PK11_R_OPENSESSION, |
|
1643 rv); |
|
1644 OPENSSL_free(sp); |
|
1645 sp = NULL; |
|
1646 goto err; |
|
1647 } |
|
1648 |
|
1649 /* |
|
1650 * It is an inherited session from our parent so it needs |
|
1651 * re-initialization. |
|
1652 */ |
|
1653 if (pk11_setup_session(sp, optype) == 0) |
|
1654 { |
|
1655 OPENSSL_free(sp); |
|
1656 sp = NULL; |
|
1657 goto err; |
|
1658 } |
|
1659 if (pk11_token_relogin(sp->session) == 0) |
|
1660 { |
|
1661 /* |
|
1662 * We will keep the session in the cache list and let |
|
1663 * the caller cope with the situation. |
|
1664 */ |
|
1665 freelist = sp; |
|
1666 sp = NULL; |
|
1667 goto err; |
|
1668 } |
|
1669 } |
|
1670 |
|
1671 if (sp->pid == 0) |
|
1672 { |
|
1673 /* It is a new session and needs initialization. */ |
|
1674 if (pk11_setup_session(sp, optype) == 0) |
|
1675 { |
|
1676 OPENSSL_free(sp); |
|
1677 sp = NULL; |
|
1678 } |
|
1679 } |
|
1680 |
|
1681 /* set new head for the list of PK11_SESSION objects */ |
|
1682 session_cache[optype].head = freelist; |
|
1683 |
|
1684 err: |
|
1685 if (sp != NULL) |
|
1686 sp->next = NULL; |
|
1687 |
|
1688 (void) pthread_mutex_unlock(freelist_lock); |
|
1689 |
|
1690 return (sp); |
|
1691 } |
|
1692 |
|
1693 |
|
1694 void |
|
1695 pk11_return_session(PK11_SESSION *sp, PK11_OPTYPE optype) |
|
1696 { |
|
1697 pthread_mutex_t *freelist_lock; |
|
1698 PK11_SESSION *freelist; |
|
1699 |
|
1700 /* |
|
1701 * If this is a session from the parent it will be taken care of and |
|
1702 * freed in pk11_get_session() as part of the post-fork clean up the |
|
1703 * next time we will ask for a new session. |
|
1704 */ |
|
1705 if (sp == NULL || sp->pid != getpid()) |
|
1706 return; |
|
1707 |
|
1708 switch (optype) |
|
1709 { |
|
1710 case OP_RSA: |
|
1711 case OP_DSA: |
|
1712 case OP_DH: |
|
1713 case OP_RAND: |
|
1714 case OP_DIGEST: |
|
1715 case OP_CIPHER: |
|
1716 freelist_lock = session_cache[optype].lock; |
|
1717 break; |
|
1718 default: |
|
1719 PK11err(PK11_F_RETURN_SESSION, |
|
1720 PK11_R_INVALID_OPERATION_TYPE); |
|
1721 return; |
|
1722 } |
|
1723 |
|
1724 (void) pthread_mutex_lock(freelist_lock); |
|
1725 freelist = session_cache[optype].head; |
|
1726 sp->next = freelist; |
|
1727 session_cache[optype].head = sp; |
|
1728 (void) pthread_mutex_unlock(freelist_lock); |
|
1729 } |
|
1730 |
|
1731 |
|
1732 /* Destroy all objects. This function is called when the engine is finished */ |
|
1733 static int pk11_free_all_sessions() |
|
1734 { |
|
1735 int ret = 1; |
|
1736 int type; |
|
1737 |
|
1738 #ifndef OPENSSL_NO_RSA |
|
1739 (void) pk11_destroy_rsa_key_objects(NULL); |
|
1740 #endif /* OPENSSL_NO_RSA */ |
|
1741 #ifndef OPENSSL_NO_DSA |
|
1742 (void) pk11_destroy_dsa_key_objects(NULL); |
|
1743 #endif /* OPENSSL_NO_DSA */ |
|
1744 #ifndef OPENSSL_NO_DH |
|
1745 (void) pk11_destroy_dh_key_objects(NULL); |
|
1746 #endif /* OPENSSL_NO_DH */ |
|
1747 (void) pk11_destroy_cipher_key_objects(NULL); |
|
1748 |
|
1749 /* |
|
1750 * We try to release as much as we can but any error means that we will |
|
1751 * return 0 on exit. |
|
1752 */ |
|
1753 for (type = 0; type < OP_MAX; type++) |
|
1754 { |
|
1755 if (pk11_free_session_list(type) == 0) |
|
1756 ret = 0; |
|
1757 } |
|
1758 |
|
1759 return (ret); |
|
1760 } |
|
1761 |
|
1762 /* |
|
1763 * Destroy session structures from the linked list specified. Free as many |
|
1764 * sessions as possible but any failure in C_CloseSession() means that we |
|
1765 * return an error on return. |
|
1766 */ |
|
1767 static int pk11_free_session_list(PK11_OPTYPE optype) |
|
1768 { |
|
1769 CK_RV rv; |
|
1770 PK11_SESSION *sp = NULL; |
|
1771 PK11_SESSION *freelist = NULL; |
|
1772 pid_t mypid = getpid(); |
|
1773 pthread_mutex_t *freelist_lock; |
|
1774 int ret = 1; |
|
1775 |
|
1776 switch (optype) |
|
1777 { |
|
1778 case OP_RSA: |
|
1779 case OP_DSA: |
|
1780 case OP_DH: |
|
1781 case OP_RAND: |
|
1782 case OP_DIGEST: |
|
1783 case OP_CIPHER: |
|
1784 freelist_lock = session_cache[optype].lock; |
|
1785 break; |
|
1786 default: |
|
1787 PK11err(PK11_F_FREE_ALL_SESSIONS, |
|
1788 PK11_R_INVALID_OPERATION_TYPE); |
|
1789 return (0); |
|
1790 } |
|
1791 |
|
1792 (void) pthread_mutex_lock(freelist_lock); |
|
1793 freelist = session_cache[optype].head; |
|
1794 while ((sp = freelist) != NULL) |
|
1795 { |
|
1796 if (sp->session != CK_INVALID_HANDLE && sp->pid == mypid) |
|
1797 { |
|
1798 rv = pFuncList->C_CloseSession(sp->session); |
|
1799 if (rv != CKR_OK) |
|
1800 { |
|
1801 PK11err_add_data(PK11_F_FREE_ALL_SESSIONS, |
|
1802 PK11_R_CLOSESESSION, rv); |
|
1803 ret = 0; |
|
1804 } |
|
1805 } |
|
1806 freelist = sp->next; |
|
1807 pk11_free_nums(sp, optype); |
|
1808 OPENSSL_free(sp); |
|
1809 } |
|
1810 |
|
1811 (void) pthread_mutex_unlock(freelist_lock); |
|
1812 return (ret); |
|
1813 } |
|
1814 |
|
1815 |
|
1816 static int |
|
1817 pk11_setup_session(PK11_SESSION *sp, PK11_OPTYPE optype) |
|
1818 { |
|
1819 CK_RV rv; |
|
1820 CK_SLOT_ID myslot; |
|
1821 |
|
1822 switch (optype) |
|
1823 { |
|
1824 case OP_RSA: |
|
1825 case OP_DSA: |
|
1826 case OP_DH: |
|
1827 myslot = pubkey_SLOTID; |
|
1828 break; |
|
1829 case OP_RAND: |
|
1830 myslot = rand_SLOTID; |
|
1831 break; |
|
1832 case OP_DIGEST: |
|
1833 case OP_CIPHER: |
|
1834 myslot = SLOTID; |
|
1835 break; |
|
1836 default: |
|
1837 PK11err(PK11_F_SETUP_SESSION, |
|
1838 PK11_R_INVALID_OPERATION_TYPE); |
|
1839 return (0); |
|
1840 } |
|
1841 |
|
1842 sp->session = CK_INVALID_HANDLE; |
|
1843 DEBUG_SLOT_SEL("%s: myslot=%d optype=%d\n", PK11_DBG, myslot, optype); |
|
1844 rv = pFuncList->C_OpenSession(myslot, CKF_SERIAL_SESSION, |
|
1845 NULL_PTR, NULL_PTR, &sp->session); |
|
1846 if (rv == CKR_CRYPTOKI_NOT_INITIALIZED) |
|
1847 { |
|
1848 /* |
|
1849 * We are probably a child process so force the |
|
1850 * reinitialize of the session |
|
1851 */ |
|
1852 pk11_library_initialized = CK_FALSE; |
|
1853 if (!pk11_library_init(NULL)) |
|
1854 return (0); |
|
1855 rv = pFuncList->C_OpenSession(myslot, CKF_SERIAL_SESSION, |
|
1856 NULL_PTR, NULL_PTR, &sp->session); |
|
1857 } |
|
1858 if (rv != CKR_OK) |
|
1859 { |
|
1860 PK11err_add_data(PK11_F_SETUP_SESSION, PK11_R_OPENSESSION, rv); |
|
1861 return (0); |
|
1862 } |
|
1863 |
|
1864 sp->pid = getpid(); |
|
1865 |
|
1866 switch (optype) |
|
1867 { |
|
1868 #ifndef OPENSSL_NO_RSA |
|
1869 case OP_RSA: |
|
1870 sp->opdata_rsa_pub_key = CK_INVALID_HANDLE; |
|
1871 sp->opdata_rsa_priv_key = CK_INVALID_HANDLE; |
|
1872 sp->opdata_rsa_pub = NULL; |
|
1873 sp->opdata_rsa_n_num = NULL; |
|
1874 sp->opdata_rsa_e_num = NULL; |
|
1875 sp->opdata_rsa_priv = NULL; |
|
1876 sp->opdata_rsa_d_num = NULL; |
|
1877 break; |
|
1878 #endif /* OPENSSL_NO_RSA */ |
|
1879 #ifndef OPENSSL_NO_DSA |
|
1880 case OP_DSA: |
|
1881 sp->opdata_dsa_pub_key = CK_INVALID_HANDLE; |
|
1882 sp->opdata_dsa_priv_key = CK_INVALID_HANDLE; |
|
1883 sp->opdata_dsa_pub = NULL; |
|
1884 sp->opdata_dsa_pub_num = NULL; |
|
1885 sp->opdata_dsa_priv = NULL; |
|
1886 sp->opdata_dsa_priv_num = NULL; |
|
1887 break; |
|
1888 #endif /* OPENSSL_NO_DSA */ |
|
1889 #ifndef OPENSSL_NO_DH |
|
1890 case OP_DH: |
|
1891 sp->opdata_dh_key = CK_INVALID_HANDLE; |
|
1892 sp->opdata_dh = NULL; |
|
1893 sp->opdata_dh_priv_num = NULL; |
|
1894 break; |
|
1895 #endif /* OPENSSL_NO_DH */ |
|
1896 case OP_CIPHER: |
|
1897 sp->opdata_cipher_key = CK_INVALID_HANDLE; |
|
1898 sp->opdata_encrypt = -1; |
|
1899 break; |
|
1900 } |
|
1901 |
|
1902 /* |
|
1903 * We always initialize the session as containing a non-persistent |
|
1904 * object. The key load functions set it to persistent if that is so. |
|
1905 */ |
|
1906 sp->persistent = CK_FALSE; |
|
1907 return (1); |
|
1908 } |
|
1909 |
|
1910 #ifndef OPENSSL_NO_RSA |
|
1911 /* |
|
1912 * Destroy all non-NULL RSA parameters. For the RSA keys by reference code, |
|
1913 * public components 'n'/'e' are the key components we use to check for the |
|
1914 * cache hit even for the private keys. So, no matter whether we are destroying |
|
1915 * a public or a private key, we always free what we can. |
|
1916 */ |
|
1917 static void |
|
1918 destroy_all_rsa_params(PK11_SESSION *sp) |
|
1919 { |
|
1920 if (sp->opdata_rsa_n_num != NULL) |
|
1921 { |
|
1922 BN_free(sp->opdata_rsa_n_num); |
|
1923 sp->opdata_rsa_n_num = NULL; |
|
1924 } |
|
1925 if (sp->opdata_rsa_e_num != NULL) |
|
1926 { |
|
1927 BN_free(sp->opdata_rsa_e_num); |
|
1928 sp->opdata_rsa_e_num = NULL; |
|
1929 } |
|
1930 if (sp->opdata_rsa_d_num != NULL) |
|
1931 { |
|
1932 BN_free(sp->opdata_rsa_d_num); |
|
1933 sp->opdata_rsa_d_num = NULL; |
|
1934 } |
|
1935 } |
|
1936 |
|
1937 /* Destroy RSA public key from single session. */ |
|
1938 int |
|
1939 pk11_destroy_rsa_object_pub(PK11_SESSION *sp, CK_BBOOL uselock) |
|
1940 { |
|
1941 int ret = 0; |
|
1942 |
|
1943 if (sp->opdata_rsa_pub_key != CK_INVALID_HANDLE) |
|
1944 { |
|
1945 TRY_OBJ_DESTROY(sp, sp->opdata_rsa_pub_key, |
|
1946 ret, uselock, OP_RSA); |
|
1947 sp->opdata_rsa_pub_key = CK_INVALID_HANDLE; |
|
1948 sp->opdata_rsa_pub = NULL; |
|
1949 destroy_all_rsa_params(sp); |
|
1950 } |
|
1951 |
|
1952 return (ret); |
|
1953 } |
|
1954 |
|
1955 /* Destroy RSA private key from single session. */ |
|
1956 int |
|
1957 pk11_destroy_rsa_object_priv(PK11_SESSION *sp, CK_BBOOL uselock) |
|
1958 { |
|
1959 int ret = 0; |
|
1960 |
|
1961 if (sp->opdata_rsa_priv_key != CK_INVALID_HANDLE) |
|
1962 { |
|
1963 TRY_OBJ_DESTROY(sp, sp->opdata_rsa_priv_key, |
|
1964 ret, uselock, OP_RSA); |
|
1965 sp->opdata_rsa_priv_key = CK_INVALID_HANDLE; |
|
1966 sp->opdata_rsa_priv = NULL; |
|
1967 destroy_all_rsa_params(sp); |
|
1968 } |
|
1969 |
|
1970 return (ret); |
|
1971 } |
|
1972 |
|
1973 /* |
|
1974 * Destroy RSA key object wrapper. If session is NULL, try to destroy all |
|
1975 * objects in the free list. |
|
1976 */ |
|
1977 int |
|
1978 pk11_destroy_rsa_key_objects(PK11_SESSION *session) |
|
1979 { |
|
1980 int ret = 1; |
|
1981 PK11_SESSION *sp = NULL; |
|
1982 PK11_SESSION *local_free_session; |
|
1983 CK_BBOOL uselock = CK_TRUE; |
|
1984 |
|
1985 if (session != NULL) |
|
1986 local_free_session = session; |
|
1987 else |
|
1988 { |
|
1989 (void) pthread_mutex_lock(session_cache[OP_RSA].lock); |
|
1990 local_free_session = session_cache[OP_RSA].head; |
|
1991 uselock = CK_FALSE; |
|
1992 } |
|
1993 |
|
1994 /* |
|
1995 * go through the list of sessions and delete key objects |
|
1996 */ |
|
1997 while ((sp = local_free_session) != NULL) |
|
1998 { |
|
1999 local_free_session = sp->next; |
|
2000 |
|
2001 /* |
|
2002 * Do not terminate list traversal if one of the |
|
2003 * destroy operations fails. |
|
2004 */ |
|
2005 if (pk11_destroy_rsa_object_pub(sp, uselock) == 0) |
|
2006 { |
|
2007 ret = 0; |
|
2008 continue; |
|
2009 } |
|
2010 if (pk11_destroy_rsa_object_priv(sp, uselock) == 0) |
|
2011 { |
|
2012 ret = 0; |
|
2013 continue; |
|
2014 } |
|
2015 } |
|
2016 |
|
2017 if (session == NULL) |
|
2018 (void) pthread_mutex_unlock(session_cache[OP_RSA].lock); |
|
2019 |
|
2020 return (ret); |
|
2021 } |
|
2022 #endif /* OPENSSL_NO_RSA */ |
|
2023 |
|
2024 #ifndef OPENSSL_NO_DSA |
|
2025 /* Destroy DSA public key from single session. */ |
|
2026 int |
|
2027 pk11_destroy_dsa_object_pub(PK11_SESSION *sp, CK_BBOOL uselock) |
|
2028 { |
|
2029 int ret = 0; |
|
2030 |
|
2031 if (sp->opdata_dsa_pub_key != CK_INVALID_HANDLE) |
|
2032 { |
|
2033 TRY_OBJ_DESTROY(sp, sp->opdata_dsa_pub_key, |
|
2034 ret, uselock, OP_DSA); |
|
2035 sp->opdata_dsa_pub_key = CK_INVALID_HANDLE; |
|
2036 sp->opdata_dsa_pub = NULL; |
|
2037 if (sp->opdata_dsa_pub_num != NULL) |
|
2038 { |
|
2039 BN_free(sp->opdata_dsa_pub_num); |
|
2040 sp->opdata_dsa_pub_num = NULL; |
|
2041 } |
|
2042 } |
|
2043 |
|
2044 return (ret); |
|
2045 } |
|
2046 |
|
2047 /* Destroy DSA private key from single session. */ |
|
2048 int |
|
2049 pk11_destroy_dsa_object_priv(PK11_SESSION *sp, CK_BBOOL uselock) |
|
2050 { |
|
2051 int ret = 0; |
|
2052 |
|
2053 if (sp->opdata_dsa_priv_key != CK_INVALID_HANDLE) |
|
2054 { |
|
2055 TRY_OBJ_DESTROY(sp, sp->opdata_dsa_priv_key, |
|
2056 ret, uselock, OP_DSA); |
|
2057 sp->opdata_dsa_priv_key = CK_INVALID_HANDLE; |
|
2058 sp->opdata_dsa_priv = NULL; |
|
2059 if (sp->opdata_dsa_priv_num != NULL) |
|
2060 { |
|
2061 BN_free(sp->opdata_dsa_priv_num); |
|
2062 sp->opdata_dsa_priv_num = NULL; |
|
2063 } |
|
2064 } |
|
2065 |
|
2066 return (ret); |
|
2067 } |
|
2068 |
|
2069 /* |
|
2070 * Destroy DSA key object wrapper. If session is NULL, try to destroy all |
|
2071 * objects in the free list. |
|
2072 */ |
|
2073 int |
|
2074 pk11_destroy_dsa_key_objects(PK11_SESSION *session) |
|
2075 { |
|
2076 int ret = 1; |
|
2077 PK11_SESSION *sp = NULL; |
|
2078 PK11_SESSION *local_free_session; |
|
2079 CK_BBOOL uselock = CK_TRUE; |
|
2080 |
|
2081 if (session != NULL) |
|
2082 local_free_session = session; |
|
2083 else |
|
2084 { |
|
2085 (void) pthread_mutex_lock(session_cache[OP_DSA].lock); |
|
2086 local_free_session = session_cache[OP_DSA].head; |
|
2087 uselock = CK_FALSE; |
|
2088 } |
|
2089 |
|
2090 /* |
|
2091 * go through the list of sessions and delete key objects |
|
2092 */ |
|
2093 while ((sp = local_free_session) != NULL) |
|
2094 { |
|
2095 local_free_session = sp->next; |
|
2096 |
|
2097 /* |
|
2098 * Do not terminate list traversal if one of the |
|
2099 * destroy operations fails. |
|
2100 */ |
|
2101 if (pk11_destroy_dsa_object_pub(sp, uselock) == 0) |
|
2102 { |
|
2103 ret = 0; |
|
2104 continue; |
|
2105 } |
|
2106 if (pk11_destroy_dsa_object_priv(sp, uselock) == 0) |
|
2107 { |
|
2108 ret = 0; |
|
2109 continue; |
|
2110 } |
|
2111 } |
|
2112 |
|
2113 if (session == NULL) |
|
2114 (void) pthread_mutex_unlock(session_cache[OP_DSA].lock); |
|
2115 |
|
2116 return (ret); |
|
2117 } |
|
2118 #endif /* OPENSSL_NO_DSA */ |
|
2119 |
|
2120 #ifndef OPENSSL_NO_DH |
|
2121 /* Destroy DH key from single session. */ |
|
2122 int |
|
2123 pk11_destroy_dh_object(PK11_SESSION *sp, CK_BBOOL uselock) |
|
2124 { |
|
2125 int ret = 0; |
|
2126 |
|
2127 if (sp->opdata_dh_key != CK_INVALID_HANDLE) |
|
2128 { |
|
2129 TRY_OBJ_DESTROY(sp, sp->opdata_dh_key, |
|
2130 ret, uselock, OP_DH); |
|
2131 sp->opdata_dh_key = CK_INVALID_HANDLE; |
|
2132 sp->opdata_dh = NULL; |
|
2133 if (sp->opdata_dh_priv_num != NULL) |
|
2134 { |
|
2135 BN_free(sp->opdata_dh_priv_num); |
|
2136 sp->opdata_dh_priv_num = NULL; |
|
2137 } |
|
2138 } |
|
2139 |
|
2140 return (ret); |
|
2141 } |
|
2142 |
|
2143 /* |
|
2144 * Destroy DH key object wrapper. |
|
2145 * |
|
2146 * arg0: pointer to PKCS#11 engine session structure |
|
2147 * if session is NULL, try to destroy all objects in the free list |
|
2148 */ |
|
2149 int |
|
2150 pk11_destroy_dh_key_objects(PK11_SESSION *session) |
|
2151 { |
|
2152 int ret = 1; |
|
2153 PK11_SESSION *sp = NULL; |
|
2154 PK11_SESSION *local_free_session; |
|
2155 CK_BBOOL uselock = CK_TRUE; |
|
2156 |
|
2157 if (session != NULL) |
|
2158 local_free_session = session; |
|
2159 else |
|
2160 { |
|
2161 (void) pthread_mutex_lock(session_cache[OP_DH].lock); |
|
2162 local_free_session = session_cache[OP_DH].head; |
|
2163 uselock = CK_FALSE; |
|
2164 } |
|
2165 |
|
2166 while ((sp = local_free_session) != NULL) |
|
2167 { |
|
2168 local_free_session = sp->next; |
|
2169 |
|
2170 /* |
|
2171 * Do not terminate list traversal if one of the |
|
2172 * destroy operations fails. |
|
2173 */ |
|
2174 if (pk11_destroy_dh_object(sp, uselock) == 0) |
|
2175 { |
|
2176 ret = 0; |
|
2177 continue; |
|
2178 } |
|
2179 } |
|
2180 if (session == NULL) |
|
2181 (void) pthread_mutex_unlock(session_cache[OP_DH].lock); |
|
2182 |
|
2183 return (ret); |
|
2184 } |
|
2185 #endif /* OPENSSL_NO_DH */ |
|
2186 |
|
2187 static int |
|
2188 pk11_destroy_object(CK_SESSION_HANDLE session, CK_OBJECT_HANDLE oh, |
|
2189 CK_BBOOL persistent) |
|
2190 { |
|
2191 CK_RV rv; |
|
2192 |
|
2193 /* |
|
2194 * We never try to destroy persistent objects which are the objects |
|
2195 * stored in the keystore. Also, we always use read-only sessions so |
|
2196 * C_DestroyObject() would be returning CKR_SESSION_READ_ONLY here. |
|
2197 */ |
|
2198 if (persistent == CK_TRUE) |
|
2199 return (1); |
|
2200 |
|
2201 rv = pFuncList->C_DestroyObject(session, oh); |
|
2202 if (rv != CKR_OK) |
|
2203 { |
|
2204 PK11err_add_data(PK11_F_DESTROY_OBJECT, PK11_R_DESTROYOBJECT, |
|
2205 rv); |
|
2206 return (0); |
|
2207 } |
|
2208 |
|
2209 return (1); |
|
2210 } |
|
2211 |
|
2212 |
|
2213 /* Symmetric ciphers and digests support functions */ |
|
2214 |
|
2215 static int |
|
2216 cipher_nid_to_pk11(int nid) |
|
2217 { |
|
2218 int i; |
|
2219 |
|
2220 for (i = 0; i < PK11_CIPHER_MAX; i++) |
|
2221 if (ciphers[i].nid == nid) |
|
2222 return (ciphers[i].id); |
|
2223 return (-1); |
|
2224 } |
|
2225 |
|
2226 static int |
|
2227 pk11_usable_ciphers(const int **nids) |
|
2228 { |
|
2229 if (cipher_count > 0) |
|
2230 *nids = cipher_nids; |
|
2231 else |
|
2232 *nids = NULL; |
|
2233 return (cipher_count); |
|
2234 } |
|
2235 |
|
2236 static int |
|
2237 pk11_usable_digests(const int **nids) |
|
2238 { |
|
2239 if (digest_count > 0) |
|
2240 *nids = digest_nids; |
|
2241 else |
|
2242 *nids = NULL; |
|
2243 return (digest_count); |
|
2244 } |
|
2245 |
|
2246 /* |
|
2247 * Init context for encryption or decryption using a symmetric key. |
|
2248 */ |
|
2249 static int pk11_init_symmetric(EVP_CIPHER_CTX *ctx, PK11_CIPHER *pcipher, |
|
2250 PK11_SESSION *sp, CK_MECHANISM_PTR pmech) |
|
2251 { |
|
2252 CK_RV rv; |
|
2253 CK_AES_CTR_PARAMS ctr_params; |
|
2254 |
|
2255 /* |
|
2256 * We expect pmech->mechanism to be already set and |
|
2257 * pParameter/ulParameterLen initialized to NULL/0 before |
|
2258 * pk11_init_symmetric() is called. |
|
2259 */ |
|
2260 OPENSSL_assert(pmech->mechanism != NULL); |
|
2261 OPENSSL_assert(pmech->pParameter == NULL); |
|
2262 OPENSSL_assert(pmech->ulParameterLen == 0); |
|
2263 |
|
2264 if (ctx->cipher->nid == NID_aes_128_ctr || |
|
2265 ctx->cipher->nid == NID_aes_192_ctr || |
|
2266 ctx->cipher->nid == NID_aes_256_ctr) |
|
2267 { |
|
2268 pmech->pParameter = (void *)(&ctr_params); |
|
2269 pmech->ulParameterLen = sizeof (ctr_params); |
|
2270 /* |
|
2271 * For now, we are limited to the fixed length of the counter, |
|
2272 * it covers the whole counter block. That's what RFC 4344 |
|
2273 * needs. For more information on internal structure of the |
|
2274 * counter block, see RFC 3686. If needed in the future, we can |
|
2275 * add code so that the counter length can be set via |
|
2276 * ENGINE_ctrl() function. |
|
2277 */ |
|
2278 ctr_params.ulCounterBits = AES_BLOCK_SIZE * 8; |
|
2279 OPENSSL_assert(pcipher->iv_len == AES_BLOCK_SIZE); |
|
2280 (void) memcpy(ctr_params.cb, ctx->iv, AES_BLOCK_SIZE); |
|
2281 } |
|
2282 else |
|
2283 { |
|
2284 if (pcipher->iv_len > 0) |
|
2285 { |
|
2286 pmech->pParameter = (void *)ctx->iv; |
|
2287 pmech->ulParameterLen = pcipher->iv_len; |
|
2288 } |
|
2289 } |
|
2290 |
|
2291 /* if we get here, the encryption needs to be reinitialized */ |
|
2292 if (ctx->encrypt) |
|
2293 rv = pFuncList->C_EncryptInit(sp->session, pmech, |
|
2294 sp->opdata_cipher_key); |
|
2295 else |
|
2296 rv = pFuncList->C_DecryptInit(sp->session, pmech, |
|
2297 sp->opdata_cipher_key); |
|
2298 |
|
2299 if (rv != CKR_OK) |
|
2300 { |
|
2301 PK11err_add_data(PK11_F_CIPHER_INIT, ctx->encrypt ? |
|
2302 PK11_R_ENCRYPTINIT : PK11_R_DECRYPTINIT, rv); |
|
2303 pk11_return_session(sp, OP_CIPHER); |
|
2304 return (0); |
|
2305 } |
|
2306 |
|
2307 return (1); |
|
2308 } |
|
2309 |
|
2310 /* ARGSUSED */ |
|
2311 static int |
|
2312 pk11_cipher_init(EVP_CIPHER_CTX *ctx, const unsigned char *key, |
|
2313 const unsigned char *iv, int enc) |
|
2314 { |
|
2315 CK_MECHANISM mech; |
|
2316 int index; |
|
2317 PK11_CIPHER_STATE *state = (PK11_CIPHER_STATE *) ctx->cipher_data; |
|
2318 PK11_SESSION *sp; |
|
2319 PK11_CIPHER *p_ciph_table_row; |
|
2320 |
|
2321 state->sp = NULL; |
|
2322 |
|
2323 index = cipher_nid_to_pk11(ctx->cipher->nid); |
|
2324 if (index < 0 || index >= PK11_CIPHER_MAX) |
|
2325 return (0); |
|
2326 |
|
2327 p_ciph_table_row = &ciphers[index]; |
|
2328 /* |
|
2329 * iv_len in the ctx->cipher structure is the maximum IV length for the |
|
2330 * current cipher and it must be less or equal to the IV length in our |
|
2331 * ciphers table. The key length must be in the allowed interval. From |
|
2332 * all cipher modes that the PKCS#11 engine supports only RC4 allows a |
|
2333 * key length to be in some range, all other NIDs have a precise key |
|
2334 * length. Every application can define its own EVP functions so this |
|
2335 * code serves as a sanity check. |
|
2336 * |
|
2337 * Note that the reason why the IV length in ctx->cipher might be |
|
2338 * greater than the actual length is that OpenSSL uses BLOCK_CIPHER_defs |
|
2339 * macro to define functions that return EVP structures for all DES |
|
2340 * modes. So, even ECB modes get 8 byte IV. |
|
2341 */ |
|
2342 if (ctx->cipher->iv_len < p_ciph_table_row->iv_len || |
|
2343 ctx->key_len < p_ciph_table_row->min_key_len || |
|
2344 ctx->key_len > p_ciph_table_row->max_key_len) |
|
2345 { |
|
2346 PK11err(PK11_F_CIPHER_INIT, PK11_R_KEY_OR_IV_LEN_PROBLEM); |
|
2347 return (0); |
|
2348 } |
|
2349 |
|
2350 if ((sp = pk11_get_session(OP_CIPHER)) == NULL) |
|
2351 return (0); |
|
2352 |
|
2353 /* if applicable, the mechanism parameter is used for IV */ |
|
2354 mech.mechanism = p_ciph_table_row->mech_type; |
|
2355 mech.pParameter = NULL; |
|
2356 mech.ulParameterLen = 0; |
|
2357 |
|
2358 /* The key object is destroyed here if it is not the current key. */ |
|
2359 (void) check_new_cipher_key(sp, key, ctx->key_len); |
|
2360 |
|
2361 /* |
|
2362 * If the key is the same and the encryption is also the same, then |
|
2363 * just reuse it. However, we must not forget to reinitialize the |
|
2364 * context that was finalized in pk11_cipher_cleanup(). |
|
2365 */ |
|
2366 if (sp->opdata_cipher_key != CK_INVALID_HANDLE && |
|
2367 sp->opdata_encrypt == ctx->encrypt) |
|
2368 { |
|
2369 state->sp = sp; |
|
2370 if (pk11_init_symmetric(ctx, p_ciph_table_row, sp, &mech) == 0) |
|
2371 return (0); |
|
2372 |
|
2373 return (1); |
|
2374 } |
|
2375 |
|
2376 /* |
|
2377 * Check if the key has been invalidated. If so, a new key object |
|
2378 * needs to be created. |
|
2379 */ |
|
2380 if (sp->opdata_cipher_key == CK_INVALID_HANDLE) |
|
2381 { |
|
2382 sp->opdata_cipher_key = pk11_get_cipher_key( |
|
2383 ctx, key, p_ciph_table_row->key_type, sp); |
|
2384 } |
|
2385 |
|
2386 if (sp->opdata_encrypt != ctx->encrypt && sp->opdata_encrypt != -1) |
|
2387 { |
|
2388 /* |
|
2389 * The previous encryption/decryption is different. Need to |
|
2390 * terminate the previous * active encryption/decryption here. |
|
2391 */ |
|
2392 if (!pk11_cipher_final(sp)) |
|
2393 { |
|
2394 pk11_return_session(sp, OP_CIPHER); |
|
2395 return (0); |
|
2396 } |
|
2397 } |
|
2398 |
|
2399 if (sp->opdata_cipher_key == CK_INVALID_HANDLE) |
|
2400 { |
|
2401 pk11_return_session(sp, OP_CIPHER); |
|
2402 return (0); |
|
2403 } |
|
2404 |
|
2405 /* now initialize the context with a new key */ |
|
2406 if (pk11_init_symmetric(ctx, p_ciph_table_row, sp, &mech) == 0) |
|
2407 return (0); |
|
2408 |
|
2409 sp->opdata_encrypt = ctx->encrypt; |
|
2410 state->sp = sp; |
|
2411 |
|
2412 return (1); |
|
2413 } |
|
2414 |
|
2415 /* |
|
2416 * When reusing the same key in an encryption/decryption session for a |
|
2417 * decryption/encryption session, we need to close the active session |
|
2418 * and recreate a new one. Note that the key is in the global session so |
|
2419 * that it needs not be recreated. |
|
2420 * |
|
2421 * It is more appropriate to use C_En/DecryptFinish here. At the time of this |
|
2422 * development, these two functions in the PKCS#11 libraries used return |
|
2423 * unexpected errors when passing in 0 length output. It may be a good |
|
2424 * idea to try them again if performance is a problem here and fix |
|
2425 * C_En/DecryptFinial if there are bugs there causing the problem. |
|
2426 */ |
|
2427 static int |
|
2428 pk11_cipher_final(PK11_SESSION *sp) |
|
2429 { |
|
2430 CK_RV rv; |
|
2431 |
|
2432 rv = pFuncList->C_CloseSession(sp->session); |
|
2433 if (rv != CKR_OK) |
|
2434 { |
|
2435 PK11err_add_data(PK11_F_CIPHER_FINAL, PK11_R_CLOSESESSION, rv); |
|
2436 return (0); |
|
2437 } |
|
2438 |
|
2439 rv = pFuncList->C_OpenSession(SLOTID, CKF_SERIAL_SESSION, |
|
2440 NULL_PTR, NULL_PTR, &sp->session); |
|
2441 if (rv != CKR_OK) |
|
2442 { |
|
2443 PK11err_add_data(PK11_F_CIPHER_FINAL, PK11_R_OPENSESSION, rv); |
|
2444 return (0); |
|
2445 } |
|
2446 |
|
2447 return (1); |
|
2448 } |
|
2449 |
|
2450 /* |
|
2451 * An engine interface function. The calling function allocates sufficient |
|
2452 * memory for the output buffer "out" to hold the results. |
|
2453 */ |
|
2454 static int |
|
2455 pk11_cipher_do_cipher(EVP_CIPHER_CTX *ctx, unsigned char *out, |
|
2456 const unsigned char *in, size_t inl) |
|
2457 { |
|
2458 PK11_CIPHER_STATE *state = (PK11_CIPHER_STATE *) ctx->cipher_data; |
|
2459 PK11_SESSION *sp; |
|
2460 CK_RV rv; |
|
2461 unsigned long outl = inl; |
|
2462 |
|
2463 if (state == NULL || state->sp == NULL) |
|
2464 return (0); |
|
2465 |
|
2466 sp = (PK11_SESSION *) state->sp; |
|
2467 |
|
2468 if (!inl) |
|
2469 return (1); |
|
2470 |
|
2471 /* RC4 is the only stream cipher we support */ |
|
2472 if (ctx->cipher->nid != NID_rc4 && (inl % ctx->cipher->block_size) != 0) |
|
2473 return (0); |
|
2474 |
|
2475 if (ctx->encrypt) |
|
2476 { |
|
2477 rv = pFuncList->C_EncryptUpdate(sp->session, |
|
2478 (unsigned char *)in, inl, out, &outl); |
|
2479 |
|
2480 if (rv != CKR_OK) |
|
2481 { |
|
2482 PK11err_add_data(PK11_F_CIPHER_DO_CIPHER, |
|
2483 PK11_R_ENCRYPTUPDATE, rv); |
|
2484 return (0); |
|
2485 } |
|
2486 } |
|
2487 else |
|
2488 { |
|
2489 rv = pFuncList->C_DecryptUpdate(sp->session, |
|
2490 (unsigned char *)in, inl, out, &outl); |
|
2491 |
|
2492 if (rv != CKR_OK) |
|
2493 { |
|
2494 PK11err_add_data(PK11_F_CIPHER_DO_CIPHER, |
|
2495 PK11_R_DECRYPTUPDATE, rv); |
|
2496 return (0); |
|
2497 } |
|
2498 } |
|
2499 |
|
2500 /* |
|
2501 * For DES_CBC, DES3_CBC, AES_CBC, and RC4, the output size is always |
|
2502 * the same size of input. |
|
2503 * The application has guaranteed to call the block ciphers with |
|
2504 * correctly aligned buffers. |
|
2505 */ |
|
2506 if (inl != outl) |
|
2507 return (0); |
|
2508 |
|
2509 return (1); |
|
2510 } |
|
2511 |
|
2512 /* |
|
2513 * Return the session to the pool. Calling C_EncryptFinal() and C_DecryptFinal() |
|
2514 * here is the right thing because in EVP_DecryptFinal_ex(), engine's |
|
2515 * do_cipher() is not even called, and in EVP_EncryptFinal_ex() it is called but |
|
2516 * the engine can't find out that it's the finalizing call. We wouldn't |
|
2517 * necessarily have to finalize the context here since reinitializing it with |
|
2518 * C_(Encrypt|Decrypt)Init() should be fine but for the sake of correctness, |
|
2519 * let's do it. Some implementations might leak memory if the previously used |
|
2520 * context is initialized without finalizing it first. |
|
2521 */ |
|
2522 static int |
|
2523 pk11_cipher_cleanup(EVP_CIPHER_CTX *ctx) |
|
2524 { |
|
2525 CK_RV rv; |
|
2526 CK_ULONG len = EVP_MAX_BLOCK_LENGTH; |
|
2527 CK_BYTE buf[EVP_MAX_BLOCK_LENGTH]; |
|
2528 PK11_CIPHER_STATE *state = ctx->cipher_data; |
|
2529 |
|
2530 if (state != NULL && state->sp != NULL) |
|
2531 { |
|
2532 /* |
|
2533 * We are not interested in the data here, we just need to get |
|
2534 * rid of the context. |
|
2535 */ |
|
2536 if (ctx->encrypt) |
|
2537 rv = pFuncList->C_EncryptFinal( |
|
2538 state->sp->session, buf, &len); |
|
2539 else |
|
2540 rv = pFuncList->C_DecryptFinal( |
|
2541 state->sp->session, buf, &len); |
|
2542 |
|
2543 if (rv != CKR_OK) |
|
2544 { |
|
2545 PK11err_add_data(PK11_F_CIPHER_CLEANUP, ctx->encrypt ? |
|
2546 PK11_R_ENCRYPTFINAL : PK11_R_DECRYPTFINAL, rv); |
|
2547 pk11_return_session(state->sp, OP_CIPHER); |
|
2548 return (0); |
|
2549 } |
|
2550 |
|
2551 pk11_return_session(state->sp, OP_CIPHER); |
|
2552 state->sp = NULL; |
|
2553 } |
|
2554 |
|
2555 return (1); |
|
2556 } |
|
2557 |
|
2558 /* |
|
2559 * Registered by the ENGINE when used to find out how to deal with |
|
2560 * a particular NID in the ENGINE. This says what we'll do at the |
|
2561 * top level - note, that list is restricted by what we answer with |
|
2562 */ |
|
2563 /* ARGSUSED */ |
|
2564 static int |
|
2565 pk11_engine_ciphers(ENGINE *e, const EVP_CIPHER **cipher, |
|
2566 const int **nids, int nid) |
|
2567 { |
|
2568 if (!cipher) |
|
2569 return (pk11_usable_ciphers(nids)); |
|
2570 |
|
2571 switch (nid) |
|
2572 { |
|
2573 case NID_des_ede3_cbc: |
|
2574 *cipher = &pk11_3des_cbc; |
|
2575 break; |
|
2576 case NID_des_cbc: |
|
2577 *cipher = &pk11_des_cbc; |
|
2578 break; |
|
2579 case NID_des_ede3_ecb: |
|
2580 *cipher = &pk11_3des_ecb; |
|
2581 break; |
|
2582 case NID_des_ecb: |
|
2583 *cipher = &pk11_des_ecb; |
|
2584 break; |
|
2585 case NID_aes_128_cbc: |
|
2586 *cipher = &pk11_aes_128_cbc; |
|
2587 break; |
|
2588 case NID_aes_192_cbc: |
|
2589 *cipher = &pk11_aes_192_cbc; |
|
2590 break; |
|
2591 case NID_aes_256_cbc: |
|
2592 *cipher = &pk11_aes_256_cbc; |
|
2593 break; |
|
2594 case NID_aes_128_ecb: |
|
2595 *cipher = &pk11_aes_128_ecb; |
|
2596 break; |
|
2597 case NID_aes_192_ecb: |
|
2598 *cipher = &pk11_aes_192_ecb; |
|
2599 break; |
|
2600 case NID_aes_256_ecb: |
|
2601 *cipher = &pk11_aes_256_ecb; |
|
2602 break; |
|
2603 case NID_aes_128_ctr: |
|
2604 *cipher = &pk11_aes_128_ctr; |
|
2605 break; |
|
2606 case NID_aes_192_ctr: |
|
2607 *cipher = &pk11_aes_192_ctr; |
|
2608 break; |
|
2609 case NID_aes_256_ctr: |
|
2610 *cipher = &pk11_aes_256_ctr; |
|
2611 break; |
|
2612 case NID_bf_cbc: |
|
2613 *cipher = &pk11_bf_cbc; |
|
2614 break; |
|
2615 case NID_rc4: |
|
2616 *cipher = &pk11_rc4; |
|
2617 break; |
|
2618 default: |
|
2619 *cipher = NULL; |
|
2620 break; |
|
2621 } |
|
2622 return (*cipher != NULL); |
|
2623 } |
|
2624 |
|
2625 /* ARGSUSED */ |
|
2626 static int |
|
2627 pk11_engine_digests(ENGINE *e, const EVP_MD **digest, |
|
2628 const int **nids, int nid) |
|
2629 { |
|
2630 if (!digest) |
|
2631 return (pk11_usable_digests(nids)); |
|
2632 |
|
2633 switch (nid) |
|
2634 { |
|
2635 case NID_md5: |
|
2636 *digest = &pk11_md5; |
|
2637 break; |
|
2638 /* |
|
2639 * A special case. For "openssl dgst -dss1 -engine pkcs11 ...", |
|
2640 * OpenSSL calls EVP_get_digestbyname() on "dss1" which ends up |
|
2641 * calling pk11_engine_digests() for NID_dsa. Internally, if an |
|
2642 * engine is not used, OpenSSL uses SHA1_Init() as expected for |
|
2643 * DSA. So, we must return pk11_sha1() for NID_dsa as well. Note |
|
2644 * that this must have changed between 0.9.8 and 1.0.0 since we |
|
2645 * did not have the problem with the 0.9.8 version. |
|
2646 */ |
|
2647 case NID_sha1: |
|
2648 case NID_dsa: |
|
2649 *digest = &pk11_sha1; |
|
2650 break; |
|
2651 case NID_sha224: |
|
2652 *digest = &pk11_sha224; |
|
2653 break; |
|
2654 case NID_sha256: |
|
2655 *digest = &pk11_sha256; |
|
2656 break; |
|
2657 case NID_sha384: |
|
2658 *digest = &pk11_sha384; |
|
2659 break; |
|
2660 case NID_sha512: |
|
2661 *digest = &pk11_sha512; |
|
2662 break; |
|
2663 default: |
|
2664 *digest = NULL; |
|
2665 break; |
|
2666 } |
|
2667 return (*digest != NULL); |
|
2668 } |
|
2669 |
|
2670 |
|
2671 /* Create a secret key object in a PKCS#11 session */ |
|
2672 static CK_OBJECT_HANDLE pk11_get_cipher_key(EVP_CIPHER_CTX *ctx, |
|
2673 const unsigned char *key, CK_KEY_TYPE key_type, PK11_SESSION *sp) |
|
2674 { |
|
2675 CK_RV rv; |
|
2676 CK_OBJECT_HANDLE h_key = CK_INVALID_HANDLE; |
|
2677 CK_OBJECT_CLASS obj_key = CKO_SECRET_KEY; |
|
2678 CK_ULONG ul_key_attr_count = 6; |
|
2679 |
|
2680 CK_ATTRIBUTE a_key_template[] = |
|
2681 { |
|
2682 {CKA_CLASS, (void*) NULL, sizeof (CK_OBJECT_CLASS)}, |
|
2683 {CKA_KEY_TYPE, (void*) NULL, sizeof (CK_KEY_TYPE)}, |
|
2684 {CKA_TOKEN, &pk11_false, sizeof (pk11_false)}, |
|
2685 {CKA_ENCRYPT, &pk11_true, sizeof (pk11_true)}, |
|
2686 {CKA_DECRYPT, &pk11_true, sizeof (pk11_true)}, |
|
2687 {CKA_VALUE, (void*) NULL, 0}, |
|
2688 }; |
|
2689 |
|
2690 /* |
|
2691 * Create secret key object in global_session. All other sessions |
|
2692 * can use the key handles. Here is why: |
|
2693 * OpenSSL will call EncryptInit and EncryptUpdate using a secret key. |
|
2694 * It may then call DecryptInit and DecryptUpdate using the same key. |
|
2695 * To use the same key object, we need to call EncryptFinal with |
|
2696 * a 0 length message. Currently, this does not work for 3DES |
|
2697 * mechanism. To get around this problem, we close the session and |
|
2698 * then create a new session to use the same key object. When a session |
|
2699 * is closed, all the object handles will be invalid. Thus, create key |
|
2700 * objects in a global session, an individual session may be closed to |
|
2701 * terminate the active operation. |
|
2702 */ |
|
2703 CK_SESSION_HANDLE session = global_session; |
|
2704 a_key_template[0].pValue = &obj_key; |
|
2705 a_key_template[1].pValue = &key_type; |
|
2706 a_key_template[5].pValue = (void *) key; |
|
2707 a_key_template[5].ulValueLen = (unsigned long) ctx->key_len; |
|
2708 |
|
2709 rv = pFuncList->C_CreateObject(session, |
|
2710 a_key_template, ul_key_attr_count, &h_key); |
|
2711 if (rv != CKR_OK) |
|
2712 { |
|
2713 PK11err_add_data(PK11_F_GET_CIPHER_KEY, PK11_R_CREATEOBJECT, |
|
2714 rv); |
|
2715 goto err; |
|
2716 } |
|
2717 |
|
2718 /* |
|
2719 * Save the key information used in this session. |
|
2720 * The max can be saved is PK11_KEY_LEN_MAX. |
|
2721 */ |
|
2722 sp->opdata_key_len = ctx->key_len > PK11_KEY_LEN_MAX ? |
|
2723 PK11_KEY_LEN_MAX : ctx->key_len; |
|
2724 (void) memcpy(sp->opdata_key, key, sp->opdata_key_len); |
|
2725 err: |
|
2726 |
|
2727 return (h_key); |
|
2728 } |
|
2729 |
|
2730 static int |
|
2731 md_nid_to_pk11(int nid) |
|
2732 { |
|
2733 int i; |
|
2734 |
|
2735 for (i = 0; i < PK11_DIGEST_MAX; i++) |
|
2736 if (digests[i].nid == nid) |
|
2737 return (digests[i].id); |
|
2738 return (-1); |
|
2739 } |
|
2740 |
|
2741 static int |
|
2742 pk11_digest_init(EVP_MD_CTX *ctx) |
|
2743 { |
|
2744 CK_RV rv; |
|
2745 CK_MECHANISM mech; |
|
2746 int index; |
|
2747 PK11_SESSION *sp; |
|
2748 PK11_DIGEST *pdp; |
|
2749 PK11_CIPHER_STATE *state = (PK11_CIPHER_STATE *) ctx->md_data; |
|
2750 |
|
2751 state->sp = NULL; |
|
2752 |
|
2753 index = md_nid_to_pk11(ctx->digest->type); |
|
2754 if (index < 0 || index >= PK11_DIGEST_MAX) |
|
2755 return (0); |
|
2756 |
|
2757 pdp = &digests[index]; |
|
2758 if ((sp = pk11_get_session(OP_DIGEST)) == NULL) |
|
2759 return (0); |
|
2760 |
|
2761 /* at present, no parameter is needed for supported digests */ |
|
2762 mech.mechanism = pdp->mech_type; |
|
2763 mech.pParameter = NULL; |
|
2764 mech.ulParameterLen = 0; |
|
2765 |
|
2766 rv = pFuncList->C_DigestInit(sp->session, &mech); |
|
2767 |
|
2768 if (rv != CKR_OK) |
|
2769 { |
|
2770 PK11err_add_data(PK11_F_DIGEST_INIT, PK11_R_DIGESTINIT, rv); |
|
2771 pk11_return_session(sp, OP_DIGEST); |
|
2772 return (0); |
|
2773 } |
|
2774 |
|
2775 state->sp = sp; |
|
2776 |
|
2777 return (1); |
|
2778 } |
|
2779 |
|
2780 static int |
|
2781 pk11_digest_update(EVP_MD_CTX *ctx, const void *data, size_t count) |
|
2782 { |
|
2783 CK_RV rv; |
|
2784 PK11_CIPHER_STATE *state = (PK11_CIPHER_STATE *) ctx->md_data; |
|
2785 |
|
2786 /* 0 length message will cause a failure in C_DigestFinal */ |
|
2787 if (count == 0) |
|
2788 return (1); |
|
2789 |
|
2790 if (state == NULL || state->sp == NULL) |
|
2791 return (0); |
|
2792 |
|
2793 rv = pFuncList->C_DigestUpdate(state->sp->session, (CK_BYTE *) data, |
|
2794 count); |
|
2795 |
|
2796 if (rv != CKR_OK) |
|
2797 { |
|
2798 PK11err_add_data(PK11_F_DIGEST_UPDATE, PK11_R_DIGESTUPDATE, rv); |
|
2799 pk11_return_session(state->sp, OP_DIGEST); |
|
2800 state->sp = NULL; |
|
2801 return (0); |
|
2802 } |
|
2803 |
|
2804 return (1); |
|
2805 } |
|
2806 |
|
2807 static int |
|
2808 pk11_digest_final(EVP_MD_CTX *ctx, unsigned char *md) |
|
2809 { |
|
2810 CK_RV rv; |
|
2811 unsigned long len; |
|
2812 PK11_CIPHER_STATE *state = (PK11_CIPHER_STATE *) ctx->md_data; |
|
2813 len = ctx->digest->md_size; |
|
2814 |
|
2815 if (state == NULL || state->sp == NULL) |
|
2816 return (0); |
|
2817 |
|
2818 rv = pFuncList->C_DigestFinal(state->sp->session, md, &len); |
|
2819 |
|
2820 if (rv != CKR_OK) |
|
2821 { |
|
2822 PK11err_add_data(PK11_F_DIGEST_FINAL, PK11_R_DIGESTFINAL, rv); |
|
2823 pk11_return_session(state->sp, OP_DIGEST); |
|
2824 state->sp = NULL; |
|
2825 return (0); |
|
2826 } |
|
2827 |
|
2828 if (ctx->digest->md_size != len) |
|
2829 return (0); |
|
2830 |
|
2831 /* |
|
2832 * Final is called and digest is returned, so return the session |
|
2833 * to the pool |
|
2834 */ |
|
2835 pk11_return_session(state->sp, OP_DIGEST); |
|
2836 state->sp = NULL; |
|
2837 |
|
2838 return (1); |
|
2839 } |
|
2840 |
|
2841 static int |
|
2842 pk11_digest_copy(EVP_MD_CTX *to, const EVP_MD_CTX *from) |
|
2843 { |
|
2844 CK_RV rv; |
|
2845 int ret = 0; |
|
2846 PK11_CIPHER_STATE *state, *state_to; |
|
2847 CK_BYTE_PTR pstate = NULL; |
|
2848 CK_ULONG ul_state_len; |
|
2849 |
|
2850 if (from->md_data == NULL || to->digest->ctx_size == 0) |
|
2851 return (1); |
|
2852 |
|
2853 /* The copy-from state */ |
|
2854 state = (PK11_CIPHER_STATE *) from->md_data; |
|
2855 if (state->sp == NULL) |
|
2856 goto err; |
|
2857 |
|
2858 /* Initialize the copy-to state */ |
|
2859 if (!pk11_digest_init(to)) |
|
2860 goto err; |
|
2861 state_to = (PK11_CIPHER_STATE *) to->md_data; |
|
2862 |
|
2863 /* Get the size of the operation state of the copy-from session */ |
|
2864 rv = pFuncList->C_GetOperationState(state->sp->session, NULL, |
|
2865 &ul_state_len); |
|
2866 |
|
2867 if (rv != CKR_OK) |
|
2868 { |
|
2869 PK11err_add_data(PK11_F_DIGEST_COPY, PK11_R_GET_OPERATION_STATE, |
|
2870 rv); |
|
2871 goto err; |
|
2872 } |
|
2873 if (ul_state_len == 0) |
|
2874 { |
|
2875 goto err; |
|
2876 } |
|
2877 |
|
2878 pstate = OPENSSL_malloc(ul_state_len); |
|
2879 if (pstate == NULL) |
|
2880 { |
|
2881 PK11err(PK11_F_DIGEST_COPY, PK11_R_MALLOC_FAILURE); |
|
2882 goto err; |
|
2883 } |
|
2884 |
|
2885 /* Get the operation state of the copy-from session */ |
|
2886 rv = pFuncList->C_GetOperationState(state->sp->session, pstate, |
|
2887 &ul_state_len); |
|
2888 |
|
2889 if (rv != CKR_OK) |
|
2890 { |
|
2891 PK11err_add_data(PK11_F_DIGEST_COPY, PK11_R_GET_OPERATION_STATE, |
|
2892 rv); |
|
2893 goto err; |
|
2894 } |
|
2895 |
|
2896 /* Set the operation state of the copy-to session */ |
|
2897 rv = pFuncList->C_SetOperationState(state_to->sp->session, pstate, |
|
2898 ul_state_len, 0, 0); |
|
2899 |
|
2900 if (rv != CKR_OK) |
|
2901 { |
|
2902 PK11err_add_data(PK11_F_DIGEST_COPY, |
|
2903 PK11_R_SET_OPERATION_STATE, rv); |
|
2904 goto err; |
|
2905 } |
|
2906 |
|
2907 ret = 1; |
|
2908 err: |
|
2909 if (pstate != NULL) |
|
2910 OPENSSL_free(pstate); |
|
2911 |
|
2912 return (ret); |
|
2913 } |
|
2914 |
|
2915 /* Return any pending session state to the pool */ |
|
2916 static int |
|
2917 pk11_digest_cleanup(EVP_MD_CTX *ctx) |
|
2918 { |
|
2919 PK11_CIPHER_STATE *state = ctx->md_data; |
|
2920 unsigned char buf[EVP_MAX_MD_SIZE]; |
|
2921 |
|
2922 if (state != NULL && state->sp != NULL) |
|
2923 { |
|
2924 /* |
|
2925 * If state->sp is not NULL then pk11_digest_final() has not |
|
2926 * been called yet. We must call it now to free any memory |
|
2927 * that might have been allocated in the token when |
|
2928 * pk11_digest_init() was called. pk11_digest_final() |
|
2929 * will return the session to the cache. |
|
2930 */ |
|
2931 if (!pk11_digest_final(ctx, buf)) |
|
2932 return (0); |
|
2933 } |
|
2934 |
|
2935 return (1); |
|
2936 } |
|
2937 |
|
2938 /* |
|
2939 * Check if the new key is the same as the key object in the session. If the key |
|
2940 * is the same, no need to create a new key object. Otherwise, the old key |
|
2941 * object needs to be destroyed and a new one will be created. Return 1 for |
|
2942 * cache hit, 0 for cache miss. Note that we must check the key length first |
|
2943 * otherwise we could end up reusing a different, longer key with the same |
|
2944 * prefix. |
|
2945 */ |
|
2946 static int check_new_cipher_key(PK11_SESSION *sp, const unsigned char *key, |
|
2947 int key_len) |
|
2948 { |
|
2949 if (sp->opdata_key_len != key_len || |
|
2950 memcmp(sp->opdata_key, key, key_len) != 0) |
|
2951 { |
|
2952 (void) pk11_destroy_cipher_key_objects(sp); |
|
2953 return (0); |
|
2954 } |
|
2955 return (1); |
|
2956 } |
|
2957 |
|
2958 /* Destroy one or more secret key objects. */ |
|
2959 static int pk11_destroy_cipher_key_objects(PK11_SESSION *session) |
|
2960 { |
|
2961 int ret = 0; |
|
2962 PK11_SESSION *sp = NULL; |
|
2963 PK11_SESSION *local_free_session; |
|
2964 |
|
2965 if (session != NULL) |
|
2966 local_free_session = session; |
|
2967 else |
|
2968 { |
|
2969 (void) pthread_mutex_lock(session_cache[OP_CIPHER].lock); |
|
2970 local_free_session = session_cache[OP_CIPHER].head; |
|
2971 } |
|
2972 |
|
2973 while ((sp = local_free_session) != NULL) |
|
2974 { |
|
2975 local_free_session = sp->next; |
|
2976 |
|
2977 if (sp->opdata_cipher_key != CK_INVALID_HANDLE) |
|
2978 { |
|
2979 /* |
|
2980 * The secret key object is created in the |
|
2981 * global_session. See pk11_get_cipher_key(). |
|
2982 */ |
|
2983 if (pk11_destroy_object(global_session, |
|
2984 sp->opdata_cipher_key, CK_FALSE) == 0) |
|
2985 goto err; |
|
2986 sp->opdata_cipher_key = CK_INVALID_HANDLE; |
|
2987 } |
|
2988 } |
|
2989 ret = 1; |
|
2990 err: |
|
2991 |
|
2992 if (session == NULL) |
|
2993 (void) pthread_mutex_unlock(session_cache[OP_CIPHER].lock); |
|
2994 |
|
2995 return (ret); |
|
2996 } |
|
2997 |
|
2998 |
|
2999 /* |
|
3000 * Public key mechanisms optionally supported |
|
3001 * |
|
3002 * CKM_RSA_X_509 |
|
3003 * CKM_RSA_PKCS |
|
3004 * CKM_DSA |
|
3005 * |
|
3006 * The first slot that supports at least one of those mechanisms is chosen as a |
|
3007 * public key slot. |
|
3008 * |
|
3009 * Symmetric ciphers optionally supported |
|
3010 * |
|
3011 * CKM_DES3_CBC |
|
3012 * CKM_DES_CBC |
|
3013 * CKM_AES_CBC |
|
3014 * CKM_DES3_ECB |
|
3015 * CKM_DES_ECB |
|
3016 * CKM_AES_ECB |
|
3017 * CKM_AES_CTR |
|
3018 * CKM_RC4 |
|
3019 * CKM_BLOWFISH_CBC |
|
3020 * |
|
3021 * Digests optionally supported |
|
3022 * |
|
3023 * CKM_MD5 |
|
3024 * CKM_SHA_1 |
|
3025 * CKM_SHA224 |
|
3026 * CKM_SHA256 |
|
3027 * CKM_SHA384 |
|
3028 * CKM_SHA512 |
|
3029 * |
|
3030 * The output of this function is a set of global variables indicating which |
|
3031 * mechanisms from RSA, DSA, DH and RAND are present, and also two arrays of |
|
3032 * mechanisms, one for symmetric ciphers and one for digests. Also, 3 global |
|
3033 * variables carry information about which slot was chosen for (a) public key |
|
3034 * mechanisms, (b) random operations, and (c) symmetric ciphers and digests. |
|
3035 */ |
|
3036 static int |
|
3037 pk11_choose_slots(int *any_slot_found) |
|
3038 { |
|
3039 CK_SLOT_ID_PTR pSlotList = NULL_PTR; |
|
3040 CK_ULONG ulSlotCount = 0; |
|
3041 CK_MECHANISM_INFO mech_info; |
|
3042 CK_TOKEN_INFO token_info; |
|
3043 int i; |
|
3044 CK_RV rv; |
|
3045 CK_SLOT_ID best_pubkey_slot_sofar; |
|
3046 CK_SLOT_ID current_slot = 0; |
|
3047 int best_number_of_mechs = 0; |
|
3048 int local_cipher_nids[PK11_CIPHER_MAX]; |
|
3049 int local_digest_nids[PK11_DIGEST_MAX]; |
|
3050 |
|
3051 /* let's initialize the output parameter */ |
|
3052 if (any_slot_found != NULL) |
|
3053 *any_slot_found = 0; |
|
3054 |
|
3055 /* Get slot list for memory allocation */ |
|
3056 rv = pFuncList->C_GetSlotList(CK_FALSE, NULL_PTR, &ulSlotCount); |
|
3057 |
|
3058 if (rv != CKR_OK) |
|
3059 { |
|
3060 PK11err_add_data(PK11_F_CHOOSE_SLOT, PK11_R_GETSLOTLIST, rv); |
|
3061 return (0); |
|
3062 } |
|
3063 |
|
3064 /* it's not an error if we didn't find any providers */ |
|
3065 if (ulSlotCount == 0) |
|
3066 { |
|
3067 DEBUG_SLOT_SEL("%s: no crypto providers found\n", PK11_DBG); |
|
3068 return (1); |
|
3069 } |
|
3070 |
|
3071 pSlotList = OPENSSL_malloc(ulSlotCount * sizeof (CK_SLOT_ID)); |
|
3072 |
|
3073 if (pSlotList == NULL) |
|
3074 { |
|
3075 PK11err(PK11_F_CHOOSE_SLOT, PK11_R_MALLOC_FAILURE); |
|
3076 return (0); |
|
3077 } |
|
3078 |
|
3079 /* Get the slot list for processing */ |
|
3080 rv = pFuncList->C_GetSlotList(CK_FALSE, pSlotList, &ulSlotCount); |
|
3081 if (rv != CKR_OK) |
|
3082 { |
|
3083 PK11err_add_data(PK11_F_CHOOSE_SLOT, PK11_R_GETSLOTLIST, rv); |
|
3084 OPENSSL_free(pSlotList); |
|
3085 return (0); |
|
3086 } |
|
3087 |
|
3088 DEBUG_SLOT_SEL("%s: provider: %s\n", PK11_DBG, def_PK11_LIBNAME); |
|
3089 DEBUG_SLOT_SEL("%s: number of slots: %d\n", PK11_DBG, ulSlotCount); |
|
3090 |
|
3091 pubkey_SLOTID = pSlotList[0]; |
|
3092 for (i = 0; i < ulSlotCount; i++) |
|
3093 { |
|
3094 current_slot = pSlotList[i]; |
|
3095 DEBUG_SLOT_SEL("%s: == checking slot: %d ==\n", PK11_DBG, |
|
3096 current_slot); |
|
3097 rv = pFuncList->C_GetTokenInfo(current_slot, &token_info); |
|
3098 if (rv != CKR_OK) |
|
3099 continue; |
|
3100 |
|
3101 DEBUG_SLOT_SEL("%s: token label: %.32s\n", PK11_DBG, |
|
3102 token_info.label); |
|
3103 |
|
3104 pk11_choose_rand_slot(token_info, current_slot); |
|
3105 |
|
3106 pk11_choose_pubkey_slot(mech_info, token_info, current_slot, |
|
3107 rv, best_number_of_mechs, best_pubkey_slot_sofar); |
|
3108 |
|
3109 (void) memset(local_cipher_nids, 0, sizeof (local_cipher_nids)); |
|
3110 (void) memset(local_digest_nids, 0, sizeof (local_digest_nids)); |
|
3111 pk11_choose_cipher_digest(local_cipher_nids, |
|
3112 local_digest_nids, pFuncList, current_slot); |
|
3113 } |
|
3114 |
|
3115 if (best_number_of_mechs == 0) |
|
3116 { |
|
3117 DEBUG_SLOT_SEL("%s: no rsa/dsa/dh\n", PK11_DBG); |
|
3118 } |
|
3119 else |
|
3120 { |
|
3121 pubkey_SLOTID = best_pubkey_slot_sofar; |
|
3122 } |
|
3123 |
|
3124 DEBUG_SLOT_SEL("%s: chosen pubkey slot: %d\n", PK11_DBG, pubkey_SLOTID); |
|
3125 DEBUG_SLOT_SEL("%s: chosen rand slot: %d\n", PK11_DBG, rand_SLOTID); |
|
3126 DEBUG_SLOT_SEL("%s: chosen cipher/digest slot: %d\n", PK11_DBG, SLOTID); |
|
3127 DEBUG_SLOT_SEL("%s: pk11_have_rsa %d\n", PK11_DBG, pk11_have_rsa); |
|
3128 DEBUG_SLOT_SEL("%s: pk11_have_dsa %d\n", PK11_DBG, pk11_have_dsa); |
|
3129 DEBUG_SLOT_SEL("%s: pk11_have_dh %d\n", PK11_DBG, pk11_have_dh); |
|
3130 DEBUG_SLOT_SEL("%s: pk11_have_random %d\n", PK11_DBG, pk11_have_random); |
|
3131 DEBUG_SLOT_SEL("%s: cipher_count %d\n", PK11_DBG, cipher_count); |
|
3132 DEBUG_SLOT_SEL("%s: digest_count %d\n", PK11_DBG, digest_count); |
|
3133 |
|
3134 if (pSlotList != NULL) |
|
3135 OPENSSL_free(pSlotList); |
|
3136 |
|
3137 #ifdef SOLARIS_HW_SLOT_SELECTION |
|
3138 OPENSSL_free(hw_cnids); |
|
3139 OPENSSL_free(hw_dnids); |
|
3140 #endif /* SOLARIS_HW_SLOT_SELECTION */ |
|
3141 |
|
3142 if (any_slot_found != NULL) |
|
3143 *any_slot_found = 1; |
|
3144 return (1); |
|
3145 } |
|
3146 |
|
3147 static void pk11_choose_rand_slot(CK_TOKEN_INFO token_info, |
|
3148 CK_SLOT_ID current_slot) |
|
3149 { |
|
3150 DEBUG_SLOT_SEL("%s: checking rand slots\n", PK11_DBG); |
|
3151 if (((token_info.flags & CKF_RNG) != 0) && !pk11_have_random) |
|
3152 { |
|
3153 DEBUG_SLOT_SEL("%s: this token has CKF_RNG flag\n", PK11_DBG); |
|
3154 pk11_have_random = CK_TRUE; |
|
3155 rand_SLOTID = current_slot; |
|
3156 } |
|
3157 } |
|
3158 |
|
3159 static void pk11_choose_pubkey_slot(CK_MECHANISM_INFO mech_info, |
|
3160 CK_TOKEN_INFO token_info, CK_SLOT_ID current_slot, CK_RV rv, |
|
3161 int best_number_of_mechs, CK_SLOT_ID best_pubkey_slot_sofar) |
|
3162 { |
|
3163 CK_BBOOL slot_has_rsa = CK_FALSE; |
|
3164 CK_BBOOL slot_has_dsa = CK_FALSE; |
|
3165 CK_BBOOL slot_has_dh = CK_FALSE; |
|
3166 int current_number_of_mechs = 0; |
|
3167 |
|
3168 DEBUG_SLOT_SEL("%s: checking pubkey slots\n", PK11_DBG); |
|
3169 |
|
3170 #ifndef OPENSSL_NO_RSA |
|
3171 /* |
|
3172 * Check if this slot is capable of signing and |
|
3173 * verifying with CKM_RSA_PKCS. |
|
3174 */ |
|
3175 rv = pFuncList->C_GetMechanismInfo(current_slot, CKM_RSA_PKCS, |
|
3176 &mech_info); |
|
3177 |
|
3178 if (rv == CKR_OK && ((mech_info.flags & CKF_SIGN) && |
|
3179 (mech_info.flags & CKF_VERIFY))) |
|
3180 { |
|
3181 /* |
|
3182 * Check if this slot is capable of encryption, |
|
3183 * decryption, sign, and verify with CKM_RSA_X_509. |
|
3184 */ |
|
3185 rv = pFuncList->C_GetMechanismInfo(current_slot, |
|
3186 CKM_RSA_X_509, &mech_info); |
|
3187 |
|
3188 if (rv == CKR_OK && ((mech_info.flags & CKF_SIGN) && |
|
3189 (mech_info.flags & CKF_VERIFY) && |
|
3190 (mech_info.flags & CKF_ENCRYPT) && |
|
3191 (mech_info.flags & CKF_VERIFY_RECOVER) && |
|
3192 (mech_info.flags & CKF_DECRYPT))) |
|
3193 { |
|
3194 slot_has_rsa = CK_TRUE; |
|
3195 current_number_of_mechs++; |
|
3196 } |
|
3197 } |
|
3198 #endif /* OPENSSL_NO_RSA */ |
|
3199 |
|
3200 #ifndef OPENSSL_NO_DSA |
|
3201 /* |
|
3202 * Check if this slot is capable of signing and |
|
3203 * verifying with CKM_DSA. |
|
3204 */ |
|
3205 rv = pFuncList->C_GetMechanismInfo(current_slot, CKM_DSA, |
|
3206 &mech_info); |
|
3207 if (rv == CKR_OK && ((mech_info.flags & CKF_SIGN) && |
|
3208 (mech_info.flags & CKF_VERIFY))) |
|
3209 { |
|
3210 slot_has_dsa = CK_TRUE; |
|
3211 current_number_of_mechs++; |
|
3212 } |
|
3213 #endif /* OPENSSL_NO_DSA */ |
|
3214 |
|
3215 #ifndef OPENSSL_NO_DH |
|
3216 /* |
|
3217 * Check if this slot is capable of DH key generataion and |
|
3218 * derivation. |
|
3219 */ |
|
3220 rv = pFuncList->C_GetMechanismInfo(current_slot, |
|
3221 CKM_DH_PKCS_KEY_PAIR_GEN, &mech_info); |
|
3222 |
|
3223 if (rv == CKR_OK && (mech_info.flags & CKF_GENERATE_KEY_PAIR)) |
|
3224 { |
|
3225 rv = pFuncList->C_GetMechanismInfo(current_slot, |
|
3226 CKM_DH_PKCS_DERIVE, &mech_info); |
|
3227 if (rv == CKR_OK && (mech_info.flags & CKF_DERIVE)) |
|
3228 { |
|
3229 slot_has_dh = CK_TRUE; |
|
3230 current_number_of_mechs++; |
|
3231 } |
|
3232 } |
|
3233 #endif /* OPENSSL_NO_DH */ |
|
3234 |
|
3235 if (current_number_of_mechs > best_number_of_mechs) |
|
3236 { |
|
3237 best_pubkey_slot_sofar = current_slot; |
|
3238 pk11_have_rsa = slot_has_rsa; |
|
3239 pk11_have_dsa = slot_has_dsa; |
|
3240 pk11_have_dh = slot_has_dh; |
|
3241 best_number_of_mechs = current_number_of_mechs; |
|
3242 /* |
|
3243 * Cache the flags for later use. We might need those if |
|
3244 * RSA keys by reference feature is used. |
|
3245 */ |
|
3246 pubkey_token_flags = token_info.flags; |
|
3247 DEBUG_SLOT_SEL("%s: pubkey flags changed to " |
|
3248 "%lu.\n", PK11_DBG, pubkey_token_flags); |
|
3249 } |
|
3250 } |
|
3251 |
|
3252 static void pk11_choose_cipher_digest(int *local_cipher_nids, |
|
3253 int *local_digest_nids, CK_FUNCTION_LIST_PTR pflist, |
|
3254 CK_SLOT_ID current_slot) |
|
3255 { |
|
3256 int current_slot_n_cipher = 0; |
|
3257 int current_slot_n_digest = 0; |
|
3258 |
|
3259 DEBUG_SLOT_SEL("%s: checking cipher/digest\n", PK11_DBG); |
|
3260 |
|
3261 pk11_find_symmetric_ciphers(pFuncList, current_slot, |
|
3262 ¤t_slot_n_cipher, local_cipher_nids); |
|
3263 |
|
3264 pk11_find_digests(pFuncList, current_slot, |
|
3265 ¤t_slot_n_digest, local_digest_nids); |
|
3266 |
|
3267 DEBUG_SLOT_SEL("%s: current_slot_n_cipher %d\n", PK11_DBG, |
|
3268 current_slot_n_cipher); |
|
3269 DEBUG_SLOT_SEL("%s: current_slot_n_digest %d\n", PK11_DBG, |
|
3270 current_slot_n_digest); |
|
3271 /* |
|
3272 * If the current slot supports more ciphers/digests than |
|
3273 * the previous best one we change the current best to this one, |
|
3274 * otherwise leave it where it is. |
|
3275 */ |
|
3276 if ((current_slot_n_cipher + current_slot_n_digest) > |
|
3277 (cipher_count + digest_count)) |
|
3278 { |
|
3279 DEBUG_SLOT_SEL("%s: changing best slot to %d\n", |
|
3280 PK11_DBG, current_slot); |
|
3281 SLOTID = current_slot; |
|
3282 cipher_count = current_slot_n_cipher; |
|
3283 digest_count = current_slot_n_digest; |
|
3284 OPENSSL_assert(cipher_count <= PK11_CIPHER_MAX); |
|
3285 OPENSSL_assert(digest_count <= PK11_DIGEST_MAX); |
|
3286 (void) memcpy(cipher_nids, local_cipher_nids, |
|
3287 sizeof (int) * cipher_count); |
|
3288 (void) memcpy(digest_nids, local_digest_nids, |
|
3289 sizeof (int) * digest_count); |
|
3290 } |
|
3291 } |
|
3292 |
|
3293 static void pk11_get_symmetric_cipher(CK_FUNCTION_LIST_PTR pflist, |
|
3294 int slot_id, int *current_slot_n_cipher, int *local_cipher_nids, |
|
3295 PK11_CIPHER *cipher) |
|
3296 { |
|
3297 static CK_MECHANISM_INFO mech_info; |
|
3298 static CK_RV rv; |
|
3299 static CK_MECHANISM_TYPE last_checked_mech = (CK_MECHANISM_TYPE)-1; |
|
3300 |
|
3301 OPENSSL_assert(cipher->mech_type != (CK_MECHANISM_TYPE)-1); |
|
3302 |
|
3303 DEBUG_SLOT_SEL("%s: checking mech: %x", PK11_DBG, cipher->mech_type); |
|
3304 if (cipher->mech_type != last_checked_mech) |
|
3305 { |
|
3306 rv = pflist->C_GetMechanismInfo(slot_id, cipher->mech_type, |
|
3307 &mech_info); |
|
3308 } |
|
3309 |
|
3310 last_checked_mech = cipher->mech_type; |
|
3311 |
|
3312 if (rv != CKR_OK) |
|
3313 { |
|
3314 DEBUG_SLOT_SEL(" not found\n"); |
|
3315 return; |
|
3316 } |
|
3317 |
|
3318 if ((mech_info.flags & CKF_ENCRYPT) && |
|
3319 (mech_info.flags & CKF_DECRYPT)) |
|
3320 { |
|
3321 if (mech_info.ulMinKeySize > cipher->min_key_len || |
|
3322 mech_info.ulMaxKeySize < cipher->max_key_len) |
|
3323 { |
|
3324 DEBUG_SLOT_SEL(" engine key size range <%i-%i> does not" |
|
3325 " match mech range <%lu-%lu>\n", |
|
3326 cipher->min_key_len, cipher->max_key_len, |
|
3327 mech_info.ulMinKeySize, mech_info.ulMaxKeySize); |
|
3328 return; |
|
3329 } |
|
3330 #ifdef SOLARIS_HW_SLOT_SELECTION |
|
3331 if (nid_in_table(cipher->nid, hw_cnids)) |
|
3332 #endif /* SOLARIS_HW_SLOT_SELECTION */ |
|
3333 { |
|
3334 DEBUG_SLOT_SEL(" usable\n"); |
|
3335 local_cipher_nids[(*current_slot_n_cipher)++] = |
|
3336 cipher->nid; |
|
3337 } |
|
3338 #ifdef SOLARIS_HW_SLOT_SELECTION |
|
3339 else |
|
3340 { |
|
3341 DEBUG_SLOT_SEL( |
|
3342 " rejected, software implementation only\n"); |
|
3343 } |
|
3344 #endif /* SOLARIS_HW_SLOT_SELECTION */ |
|
3345 } |
|
3346 else |
|
3347 { |
|
3348 DEBUG_SLOT_SEL(" unusable\n"); |
|
3349 } |
|
3350 |
|
3351 return; |
|
3352 } |
|
3353 |
|
3354 static void pk11_get_digest(CK_FUNCTION_LIST_PTR pflist, int slot_id, |
|
3355 int *current_slot_n_digest, int *local_digest_nids, PK11_DIGEST *digest) |
|
3356 { |
|
3357 CK_MECHANISM_INFO mech_info; |
|
3358 CK_RV rv; |
|
3359 |
|
3360 DEBUG_SLOT_SEL("%s: checking mech: %x", PK11_DBG, digest->mech_type); |
|
3361 rv = pflist->C_GetMechanismInfo(slot_id, digest->mech_type, &mech_info); |
|
3362 |
|
3363 if (rv != CKR_OK) |
|
3364 { |
|
3365 DEBUG_SLOT_SEL(" not found\n"); |
|
3366 return; |
|
3367 } |
|
3368 |
|
3369 if (mech_info.flags & CKF_DIGEST) |
|
3370 { |
|
3371 #ifdef SOLARIS_HW_SLOT_SELECTION |
|
3372 if (nid_in_table(digest->nid, hw_dnids)) |
|
3373 #endif /* SOLARIS_HW_SLOT_SELECTION */ |
|
3374 { |
|
3375 DEBUG_SLOT_SEL(" usable\n"); |
|
3376 local_digest_nids[(*current_slot_n_digest)++] = |
|
3377 digest->nid; |
|
3378 } |
|
3379 #ifdef SOLARIS_HW_SLOT_SELECTION |
|
3380 else |
|
3381 { |
|
3382 DEBUG_SLOT_SEL( |
|
3383 " rejected, software implementation only\n"); |
|
3384 } |
|
3385 #endif /* SOLARIS_HW_SLOT_SELECTION */ |
|
3386 } |
|
3387 else |
|
3388 { |
|
3389 DEBUG_SLOT_SEL(" unusable\n"); |
|
3390 } |
|
3391 |
|
3392 return; |
|
3393 } |
|
3394 |
|
3395 /* Find what symmetric ciphers this slot supports. */ |
|
3396 static void pk11_find_symmetric_ciphers(CK_FUNCTION_LIST_PTR pflist, |
|
3397 CK_SLOT_ID current_slot, int *current_slot_n_cipher, int *local_cipher_nids) |
|
3398 { |
|
3399 int i; |
|
3400 |
|
3401 for (i = 0; i < PK11_CIPHER_MAX; ++i) |
|
3402 { |
|
3403 pk11_get_symmetric_cipher(pflist, current_slot, |
|
3404 current_slot_n_cipher, local_cipher_nids, &ciphers[i]); |
|
3405 } |
|
3406 } |
|
3407 |
|
3408 /* Find what digest algorithms this slot supports. */ |
|
3409 static void pk11_find_digests(CK_FUNCTION_LIST_PTR pflist, |
|
3410 CK_SLOT_ID current_slot, int *current_slot_n_digest, int *local_digest_nids) |
|
3411 { |
|
3412 int i; |
|
3413 |
|
3414 for (i = 0; i < PK11_DIGEST_MAX; ++i) |
|
3415 { |
|
3416 pk11_get_digest(pflist, current_slot, current_slot_n_digest, |
|
3417 local_digest_nids, &digests[i]); |
|
3418 } |
|
3419 } |
|
3420 |
|
3421 #ifdef SOLARIS_HW_SLOT_SELECTION |
|
3422 /* |
|
3423 * It would be great if we could use pkcs11_kernel directly since this library |
|
3424 * offers hardware slots only. That's the easiest way to achieve the situation |
|
3425 * where we use the hardware accelerators when present and OpenSSL native code |
|
3426 * otherwise. That presumes the fact that OpenSSL native code is faster than the |
|
3427 * code in the soft token. It's a logical assumption - Crypto Framework has some |
|
3428 * inherent overhead so going there for the software implementation of a |
|
3429 * mechanism should be logically slower in contrast to the OpenSSL native code, |
|
3430 * presuming that both implementations are of similar speed. For example, the |
|
3431 * soft token for AES is roughly three times slower than OpenSSL for 64 byte |
|
3432 * blocks and still 20% slower for 8KB blocks. So, if we want to ship products |
|
3433 * that use the PKCS#11 engine by default, we must somehow avoid that regression |
|
3434 * on machines without hardware acceleration. That's why switching to the |
|
3435 * pkcs11_kernel library seems like a very good idea. |
|
3436 * |
|
3437 * The problem is that OpenSSL built with SunStudio is roughly 2x slower for |
|
3438 * asymmetric operations (RSA/DSA/DH) than the soft token built with the same |
|
3439 * compiler. That means that if we switched to pkcs11_kernel from the libpkcs11 |
|
3440 * library, we would have had a performance regression on machines without |
|
3441 * hardware acceleration for asymmetric operations for all applications that use |
|
3442 * the PKCS#11 engine. There is one such application - Apache web server since |
|
3443 * it's shipped configured to use the PKCS#11 engine by default. Having said |
|
3444 * that, we can't switch to the pkcs11_kernel library now and have to come with |
|
3445 * a solution that, on non-accelerated machines, uses the OpenSSL native code |
|
3446 * for all symmetric ciphers and digests while it uses the soft token for |
|
3447 * asymmetric operations. |
|
3448 * |
|
3449 * This is the idea: dlopen() pkcs11_kernel directly and find out what |
|
3450 * mechanisms are there. We don't care about duplications (more slots can |
|
3451 * support the same mechanism), we just want to know what mechanisms can be |
|
3452 * possibly supported in hardware on that particular machine. As said before, |
|
3453 * pkcs11_kernel will show you hardware providers only. |
|
3454 * |
|
3455 * Then, we rely on the fact that since we use libpkcs11 library we will find |
|
3456 * the metaslot. When we go through the metaslot's mechanisms for symmetric |
|
3457 * ciphers and digests, we check that any found mechanism is in the table |
|
3458 * created using the pkcs11_kernel library. So, as a result we have two arrays |
|
3459 * of mechanisms that were advertised as supported in hardware which was the |
|
3460 * goal of that whole exercise. Thus, we can use libpkcs11 but avoid soft token |
|
3461 * code for symmetric ciphers and digests. See pk11_choose_slots() for more |
|
3462 * information. |
|
3463 * |
|
3464 * This is Solaris specific code, if SOLARIS_HW_SLOT_SELECTION is not defined |
|
3465 * the code won't be used. |
|
3466 */ |
|
3467 #if defined(__sparcv9) || defined(__x86_64) || defined(__amd64) |
|
3468 static const char pkcs11_kernel[] = "/usr/lib/security/64/pkcs11_kernel.so.1"; |
|
3469 #else |
|
3470 static const char pkcs11_kernel[] = "/usr/lib/security/pkcs11_kernel.so.1"; |
|
3471 #endif |
|
3472 |
|
3473 /* |
|
3474 * Check hardware capabilities of the machines. The output are two lists, |
|
3475 * hw_cnids and hw_dnids, that contain hardware mechanisms found in all hardware |
|
3476 * providers together. They are not sorted and may contain duplicate mechanisms. |
|
3477 */ |
|
3478 static int check_hw_mechanisms(void) |
|
3479 { |
|
3480 int i; |
|
3481 CK_RV rv; |
|
3482 void *handle; |
|
3483 CK_C_GetFunctionList p; |
|
3484 CK_TOKEN_INFO token_info; |
|
3485 CK_ULONG ulSlotCount = 0; |
|
3486 int n_cipher = 0, n_digest = 0; |
|
3487 CK_FUNCTION_LIST_PTR pflist = NULL; |
|
3488 CK_SLOT_ID_PTR pSlotList = NULL_PTR; |
|
3489 int *tmp_hw_cnids = NULL, *tmp_hw_dnids = NULL; |
|
3490 int hw_ctable_size, hw_dtable_size; |
|
3491 |
|
3492 DEBUG_SLOT_SEL("%s: SOLARIS_HW_SLOT_SELECTION code running\n", |
|
3493 PK11_DBG); |
|
3494 /* |
|
3495 * Use RTLD_GROUP to limit the pkcs11_kernel provider to its own |
|
3496 * symbols, which prevents it from mistakenly accessing C_* functions |
|
3497 * from the top-level PKCS#11 library. |
|
3498 */ |
|
3499 if ((handle = dlopen(pkcs11_kernel, RTLD_LAZY | RTLD_GROUP)) == NULL) |
|
3500 { |
|
3501 PK11err(PK11_F_CHECK_HW_MECHANISMS, PK11_R_DSO_FAILURE); |
|
3502 goto err; |
|
3503 } |
|
3504 |
|
3505 if ((p = (CK_C_GetFunctionList)dlsym(handle, |
|
3506 PK11_GET_FUNCTION_LIST)) == NULL) |
|
3507 { |
|
3508 PK11err(PK11_F_CHECK_HW_MECHANISMS, PK11_R_DSO_FAILURE); |
|
3509 goto err; |
|
3510 } |
|
3511 |
|
3512 /* get the full function list from the loaded library */ |
|
3513 if (p(&pflist) != CKR_OK) |
|
3514 { |
|
3515 PK11err(PK11_F_CHECK_HW_MECHANISMS, PK11_R_DSO_FAILURE); |
|
3516 goto err; |
|
3517 } |
|
3518 |
|
3519 rv = pflist->C_Initialize(NULL_PTR); |
|
3520 if ((rv != CKR_OK) && (rv != CKR_CRYPTOKI_ALREADY_INITIALIZED)) |
|
3521 { |
|
3522 PK11err_add_data(PK11_F_CHECK_HW_MECHANISMS, |
|
3523 PK11_R_INITIALIZE, rv); |
|
3524 goto err; |
|
3525 } |
|
3526 |
|
3527 if (pflist->C_GetSlotList(0, NULL_PTR, &ulSlotCount) != CKR_OK) |
|
3528 { |
|
3529 PK11err(PK11_F_CHECK_HW_MECHANISMS, PK11_R_GETSLOTLIST); |
|
3530 goto err; |
|
3531 } |
|
3532 |
|
3533 /* no slots, set the hw mechanism tables as empty */ |
|
3534 if (ulSlotCount == 0) |
|
3535 { |
|
3536 DEBUG_SLOT_SEL("%s: no hardware mechanisms found\n", PK11_DBG); |
|
3537 hw_cnids = OPENSSL_malloc(sizeof (int)); |
|
3538 hw_dnids = OPENSSL_malloc(sizeof (int)); |
|
3539 if (hw_cnids == NULL || hw_dnids == NULL) |
|
3540 { |
|
3541 PK11err(PK11_F_CHECK_HW_MECHANISMS, |
|
3542 PK11_R_MALLOC_FAILURE); |
|
3543 return (0); |
|
3544 } |
|
3545 /* this means empty tables */ |
|
3546 hw_cnids[0] = NID_undef; |
|
3547 hw_dnids[0] = NID_undef; |
|
3548 return (1); |
|
3549 } |
|
3550 |
|
3551 pSlotList = OPENSSL_malloc(ulSlotCount * sizeof (CK_SLOT_ID)); |
|
3552 if (pSlotList == NULL) |
|
3553 { |
|
3554 PK11err(PK11_F_CHECK_HW_MECHANISMS, PK11_R_MALLOC_FAILURE); |
|
3555 goto err; |
|
3556 } |
|
3557 |
|
3558 /* Get the slot list for processing */ |
|
3559 if (pflist->C_GetSlotList(0, pSlotList, &ulSlotCount) != CKR_OK) |
|
3560 { |
|
3561 PK11err(PK11_F_CHECK_HW_MECHANISMS, PK11_R_GETSLOTLIST); |
|
3562 goto err; |
|
3563 } |
|
3564 |
|
3565 /* |
|
3566 * We don't care about duplicate mechanisms in multiple slots and also |
|
3567 * reserve one slot for the terminal NID_undef which we use to stop the |
|
3568 * search. |
|
3569 */ |
|
3570 hw_ctable_size = ulSlotCount * PK11_CIPHER_MAX + 1; |
|
3571 hw_dtable_size = ulSlotCount * PK11_DIGEST_MAX + 1; |
|
3572 tmp_hw_cnids = OPENSSL_malloc(hw_ctable_size * sizeof (int)); |
|
3573 tmp_hw_dnids = OPENSSL_malloc(hw_dtable_size * sizeof (int)); |
|
3574 if (tmp_hw_cnids == NULL || tmp_hw_dnids == NULL) |
|
3575 { |
|
3576 PK11err(PK11_F_CHECK_HW_MECHANISMS, PK11_R_MALLOC_FAILURE); |
|
3577 goto err; |
|
3578 } |
|
3579 |
|
3580 /* |
|
3581 * Do not use memset since we should not rely on the fact that NID_undef |
|
3582 * is zero now. |
|
3583 */ |
|
3584 for (i = 0; i < hw_ctable_size; ++i) |
|
3585 tmp_hw_cnids[i] = NID_undef; |
|
3586 for (i = 0; i < hw_dtable_size; ++i) |
|
3587 tmp_hw_dnids[i] = NID_undef; |
|
3588 |
|
3589 DEBUG_SLOT_SEL("%s: provider: %s\n", PK11_DBG, pkcs11_kernel); |
|
3590 DEBUG_SLOT_SEL("%s: found %d hardware slots\n", PK11_DBG, ulSlotCount); |
|
3591 DEBUG_SLOT_SEL("%s: now looking for mechs supported in hw\n", |
|
3592 PK11_DBG); |
|
3593 |
|
3594 for (i = 0; i < ulSlotCount; i++) |
|
3595 { |
|
3596 if (pflist->C_GetTokenInfo(pSlotList[i], &token_info) != CKR_OK) |
|
3597 continue; |
|
3598 |
|
3599 DEBUG_SLOT_SEL("%s: token label: %.32s\n", PK11_DBG, |
|
3600 token_info.label); |
|
3601 |
|
3602 /* |
|
3603 * We are filling the hw mech tables here. Global tables are |
|
3604 * still NULL so all mechanisms are put into tmp tables. |
|
3605 */ |
|
3606 pk11_find_symmetric_ciphers(pflist, pSlotList[i], |
|
3607 &n_cipher, tmp_hw_cnids); |
|
3608 pk11_find_digests(pflist, pSlotList[i], |
|
3609 &n_digest, tmp_hw_dnids); |
|
3610 } |
|
3611 |
|
3612 /* |
|
3613 * Since we are part of a library (libcrypto.so), calling this function |
|
3614 * may have side-effects. Also, C_Finalize() is triggered by |
|
3615 * dlclose(3C). |
|
3616 */ |
|
3617 #if 0 |
|
3618 pflist->C_Finalize(NULL); |
|
3619 #endif |
|
3620 OPENSSL_free(pSlotList); |
|
3621 (void) dlclose(handle); |
|
3622 hw_cnids = tmp_hw_cnids; |
|
3623 hw_dnids = tmp_hw_dnids; |
|
3624 |
|
3625 DEBUG_SLOT_SEL("%s: hw mechs check complete\n", PK11_DBG); |
|
3626 return (1); |
|
3627 |
|
3628 err: |
|
3629 if (pSlotList != NULL) |
|
3630 OPENSSL_free(pSlotList); |
|
3631 if (tmp_hw_cnids != NULL) |
|
3632 OPENSSL_free(tmp_hw_cnids); |
|
3633 if (tmp_hw_dnids != NULL) |
|
3634 OPENSSL_free(tmp_hw_dnids); |
|
3635 |
|
3636 return (0); |
|
3637 } |
|
3638 |
|
3639 /* |
|
3640 * Check presence of a NID in the table of NIDs unless the mechanism is |
|
3641 * supported directly in a CPU instruction set. The table may be NULL (i.e., |
|
3642 * non-existent). |
|
3643 */ |
|
3644 static int nid_in_table(int nid, int *nid_table) |
|
3645 { |
|
3646 int i = 0; |
|
3647 |
|
3648 /* |
|
3649 * Special case first. NULL means that we are initializing a new table. |
|
3650 */ |
|
3651 if (nid_table == NULL) |
|
3652 return (1); |
|
3653 |
|
3654 #if defined(__x86) |
|
3655 /* |
|
3656 * On Intel, if we have AES-NI instruction set we route AES to the |
|
3657 * Crypto Framework. Intel CPUs do not have other instruction sets for |
|
3658 * HW crypto acceleration so we check the HW NID table for any other |
|
3659 * mechanism. |
|
3660 */ |
|
3661 if (hw_aes_instruction_set_present() == 1) |
|
3662 { |
|
3663 switch (nid) |
|
3664 { |
|
3665 case NID_aes_128_ecb: |
|
3666 case NID_aes_192_ecb: |
|
3667 case NID_aes_256_ecb: |
|
3668 case NID_aes_128_cbc: |
|
3669 case NID_aes_192_cbc: |
|
3670 case NID_aes_256_cbc: |
|
3671 case NID_aes_128_ctr: |
|
3672 case NID_aes_192_ctr: |
|
3673 case NID_aes_256_ctr: |
|
3674 return (1); |
|
3675 } |
|
3676 } |
|
3677 #elif defined(__sparc) |
|
3678 if (hw_aes_instruction_set_present() == 1) |
|
3679 return (1); |
|
3680 #endif |
|
3681 |
|
3682 /* The table is never full, there is always at least one NID_undef. */ |
|
3683 while (nid_table[i] != NID_undef) |
|
3684 { |
|
3685 if (nid_table[i++] == nid) |
|
3686 { |
|
3687 DEBUG_SLOT_SEL(" (NID %d in hw table, idx %d)", nid, i); |
|
3688 return (1); |
|
3689 } |
|
3690 } |
|
3691 |
|
3692 return (0); |
|
3693 } |
|
3694 |
|
3695 /* Do we have an AES instruction set? */ |
|
3696 static int |
|
3697 hw_aes_instruction_set_present(void) |
|
3698 { |
|
3699 static int present = -1; |
|
3700 |
|
3701 if (present == -1) |
|
3702 { |
|
3703 uint_t ui = 0; |
|
3704 |
|
3705 (void) getisax(&ui, 1); |
|
3706 |
|
3707 #if defined(__amd64) || defined(__i386) |
|
3708 present = (ui & AV_386_AES) > 0; |
|
3709 #elif defined(__sparc) |
|
3710 present = (ui & (AV_SPARC_AES|AV_SPARC_FJAES)) > 0; |
|
3711 #endif |
|
3712 } |
|
3713 |
|
3714 return (present); |
|
3715 } |
|
3716 |
|
3717 #endif /* SOLARIS_HW_SLOT_SELECTION */ |
|
3718 |
|
3719 #endif /* OPENSSL_NO_HW_PK11 */ |
|
3720 #endif /* OPENSSL_NO_HW */ |
|