1ASN1_generate_nconf(3) OpenSSL ASN1_generate_nconf(3)
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6 ASN1_generate_nconf, ASN1_generate_v3 - ASN1 generation functions
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9 #include <openssl/asn1.h>
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11 ASN1_TYPE *ASN1_generate_nconf(char *str, CONF *nconf);
12 ASN1_TYPE *ASN1_generate_v3(char *str, X509V3_CTX *cnf);
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15 These functions generate the ASN1 encoding of a string in an ASN1_TYPE
16 structure.
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18 str contains the string to encode nconf or cnf contains the optional
19 configuration information where additional strings will be read from.
20 nconf will typically come from a config file wherease cnf is obtained
21 from an X509V3_CTX structure which will typically be used by X509 v3
22 certificate extension functions. cnf or nconf can be set to NULL if no
23 additional configuration will be used.
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26 The actual data encoded is determined by the string str and the
27 configuration information. The general format of the string is:
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29 [modifier,]type[:value]
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31 That is zero or more comma separated modifiers followed by a type
32 followed by an optional colon and a value. The formats of type, value
33 and modifier are explained below.
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35 SUPPORTED TYPES
36 The supported types are listed below. Unless otherwise specified only
37 the ASCII format is permissible.
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39 BOOLEAN, BOOL
40 This encodes a boolean type. The value string is mandatory and should
41 be TRUE or FALSE. Additionally TRUE, true, Y, y, YES, yes, FALSE,
42 false, N, n, NO and no are acceptable.
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44 NULL
45 Encode the NULL type, the value string must not be present.
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47 INTEGER, INT
48 Encodes an ASN1 INTEGER type. The value string represents the value
49 of the integer, it can be prefaced by a minus sign and is normally
50 interpreted as a decimal value unless the prefix 0x is included.
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52 ENUMERATED, ENUM
53 Encodes the ASN1 ENUMERATED type, it is otherwise identical to
54 INTEGER.
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56 OBJECT, OID
57 Encodes an ASN1 OBJECT IDENTIFIER, the value string can be a short
58 name, a long name or numerical format.
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60 UTCTIME, UTC
61 Encodes an ASN1 UTCTime structure, the value should be in the format
62 YYMMDDHHMMSSZ.
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64 GENERALIZEDTIME, GENTIME
65 Encodes an ASN1 GeneralizedTime structure, the value should be in the
66 format YYYYMMDDHHMMSSZ.
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68 OCTETSTRING, OCT
69 Encodes an ASN1 OCTET STRING. value represents the contents of this
70 structure, the format strings ASCII and HEX can be used to specify
71 the format of value.
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73 BITSTRING, BITSTR
74 Encodes an ASN1 BIT STRING. value represents the contents of this
75 structure, the format strings ASCII, HEX and BITLIST can be used to
76 specify the format of value.
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78 If the format is anything other than BITLIST the number of unused
79 bits is set to zero.
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81 UNIVERSALSTRING, UNIV, IA5, IA5STRING, UTF8, UTF8String, BMP,
82 BMPSTRING, VISIBLESTRING, VISIBLE, PRINTABLESTRING, PRINTABLE, T61,
83 T61STRING, TELETEXSTRING, GeneralString, NUMERICSTRING, NUMERIC
84 These encode the corresponding string types. value represents the
85 contents of this structure. The format can be ASCII or UTF8.
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87 SEQUENCE, SEQ, SET
88 Formats the result as an ASN1 SEQUENCE or SET type. value should be a
89 section name which will contain the contents. The field names in the
90 section are ignored and the values are in the generated string
91 format. If value is absent then an empty SEQUENCE will be encoded.
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93 MODIFIERS
94 Modifiers affect the following structure, they can be used to add
95 EXPLICIT or IMPLICIT tagging, add wrappers or to change the string
96 format of the final type and value. The supported formats are
97 documented below.
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99 EXPLICIT, EXP
100 Add an explicit tag to the following structure. This string should be
101 followed by a colon and the tag value to use as a decimal value.
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103 By following the number with U, A, P or C UNIVERSAL, APPLICATION,
104 PRIVATE or CONTEXT SPECIFIC tagging can be used, the default is
105 CONTEXT SPECIFIC.
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107 IMPLICIT, IMP
108 This is the same as EXPLICIT except IMPLICIT tagging is used instead.
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110 OCTWRAP, SEQWRAP, SETWRAP, BITWRAP
111 The following structure is surrounded by an OCTET STRING, a SEQUENCE,
112 a SET or a BIT STRING respectively. For a BIT STRING the number of
113 unused bits is set to zero.
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115 FORMAT
116 This specifies the format of the ultimate value. It should be
117 followed by a colon and one of the strings ASCII, UTF8, HEX or
118 BITLIST.
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120 If no format specifier is included then ASCII is used. If UTF8 is
121 specified then the value string must be a valid UTF8 string. For HEX
122 the output must be a set of hex digits. BITLIST (which is only valid
123 for a BIT STRING) is a comma separated list of the indices of the set
124 bits, all other bits are zero.
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127 A simple IA5String:
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129 IA5STRING:Hello World
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131 An IA5String explicitly tagged:
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133 EXPLICIT:0,IA5STRING:Hello World
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135 An IA5String explicitly tagged using APPLICATION tagging:
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137 EXPLICIT:0A,IA5STRING:Hello World
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139 A BITSTRING with bits 1 and 5 set and all others zero:
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141 FORMAT:BITLIST,BITSTRING:1,5
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143 A more complex example using a config file to produce a SEQUENCE
144 consiting of a BOOL an OID and a UTF8String:
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146 asn1 = SEQUENCE:seq_section
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148 [seq_section]
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150 field1 = BOOLEAN:TRUE
151 field2 = OID:commonName
152 field3 = UTF8:Third field
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154 This example produces an RSAPrivateKey structure, this is the key
155 contained in the file client.pem in all OpenSSL distributions (note:
156 the field names such as 'coeff' are ignored and are present just for
157 clarity):
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159 asn1=SEQUENCE:private_key
160 [private_key]
161 version=INTEGER:0
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163 n=INTEGER:0xBB6FE79432CC6EA2D8F970675A5A87BFBE1AFF0BE63E879F2AFFB93644\
164 D4D2C6D000430DEC66ABF47829E74B8C5108623A1C0EE8BE217B3AD8D36D5EB4FCA1D9
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166 e=INTEGER:0x010001
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168 d=INTEGER:0x6F05EAD2F27FFAEC84BEC360C4B928FD5F3A9865D0FCAAD291E2A52F4A\
169 F810DC6373278C006A0ABBA27DC8C63BF97F7E666E27C5284D7D3B1FFFE16B7A87B51D
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171 p=INTEGER:0xF3929B9435608F8A22C208D86795271D54EBDFB09DDEF539AB083DA912\
172 D4BD57
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174 q=INTEGER:0xC50016F89DFF2561347ED1186A46E150E28BF2D0F539A1594BBD7FE467\
175 46EC4F
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177 exp1=INTEGER:0x9E7D4326C924AFC1DEA40B45650134966D6F9DFA3A7F9D698CD4ABEA\
178 9C0A39B9
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180 exp2=INTEGER:0xBA84003BB95355AFB7C50DF140C60513D0BA51D637272E355E397779\
181 E7B2458F
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183 coeff=INTEGER:0x30B9E4F2AFA5AC679F920FC83F1F2DF1BAF1779CF989447FABC2F5\
184 628657053A
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186 This example is the corresponding public key in a SubjectPublicKeyInfo
187 structure:
188
189 # Start with a SEQUENCE
190 asn1=SEQUENCE:pubkeyinfo
191
192 # pubkeyinfo contains an algorithm identifier and the public key wrapped
193 # in a BIT STRING
194 [pubkeyinfo]
195 algorithm=SEQUENCE:rsa_alg
196 pubkey=BITWRAP,SEQUENCE:rsapubkey
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198 # algorithm ID for RSA is just an OID and a NULL
199 [rsa_alg]
200 algorithm=OID:rsaEncryption
201 parameter=NULL
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203 # Actual public key: modulus and exponent
204 [rsapubkey]
205 n=INTEGER:0xBB6FE79432CC6EA2D8F970675A5A87BFBE1AFF0BE63E879F2AFFB93644\
206 D4D2C6D000430DEC66ABF47829E74B8C5108623A1C0EE8BE217B3AD8D36D5EB4FCA1D9
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208 e=INTEGER:0x010001
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211 ASN1_generate_nconf() and ASN1_generate_v3() return the encoded data as
212 an ASN1_TYPE structure or NULL if an error occurred.
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214 The error codes that can be obtained by ERR_get_error(3).
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217 ERR_get_error(3)
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220 ASN1_generate_nconf() and ASN1_generate_v3() were added to OpenSSL
221 0.9.8
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2251.0.2o 2020-08-01 ASN1_generate_nconf(3)