Next: Introduction, Up: (dir) [Contents][Index]
This manual is for GNU Libtasn1 (version 4.14, 29 March 2019), which is a library for Abstract Syntax Notation One (ASN.1) and Distinguished Encoding Rules (DER) manipulation.
Copyright © 2001-2019 Free Software Foundation, Inc.
Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.3 or any later version published by the Free Software Foundation; with no Invariant Sections, no Front-Cover Texts, and no Back-Cover Texts. A copy of the license is included in the section entitled “GNU Free Documentation License”.
• Introduction: | ||
• ASN.1 structure handling: | ||
• Utilities: | ||
• Function reference: | ||
• Copying Information: | ||
Indices | ||
---|---|---|
• Concept Index: | Index of concepts and programs. | |
• Function and Data Index: | Index of functions, variables and data types. |
Next: ASN.1 structure handling, Previous: Top, Up: Top [Contents][Index]
This document describes the Libtasn1 library that provides Abstract Syntax Notation One (ASN.1, as specified by the X.680 ITU-T recommendation) parsing and structures management, and Distinguished Encoding Rules (DER, as per X.690) encoding and decoding functions.
The main features of this library are:
Next: Utilities, Previous: Introduction, Up: Top [Contents][Index]
• ASN.1 syntax: | ||
• Naming: | ||
• Simple parsing: | ||
• Library Notes: | ||
• Future developments: |
Next: Naming, Up: ASN.1 structure handling [Contents][Index]
The parser is case sensitive. The comments begin with --
and
end either with another --
, or at the end of the respective
line, whichever comes first. The C-style /*
, */
comments are not supported.
For an example of the syntax, check the pkix.asn file distributed with the library.
ASN.1 definitions must follow the syntax below:
definitions_name {<object definition>} DEFINITIONS <EXPLICIT or IMPLICIT> TAGS ::= BEGIN <type and constants definitions> END
The ::=
token must be separate from other elements, so the
following declaration is invalid:
-- INCORRECT Version ::=INTEGER
The correct form is:
Version ::= INTEGER
Here is the list of types that the parser can manage:
INTEGER
;
ENUMERATED
;
BOOLEAN
;
OBJECT IDENTIFIER
;
NULL
;
BIT STRING
;
OCTET STRING
;
UTCTime
;
GeneralizedTime
;
GeneralString
;
NumericString
;
IA5String
;
TeletexString
;
PrintableString
;
UniversalString
;
BMPString
;
UTF8String
;
VisibleString
;
SEQUENCE
;
SEQUENCE OF
;
SET
;
SET OF
;
CHOICE
;
ANY
;
ANY DEFINED BY
.
This version doesn’t handle the REAL
type. It doesn’t support
the AUTOMATIC TAGS
option, and the EXPORT
and
IMPORT
sections, either.
The SIZE
constraints are allowed, but no check is done on them.
Next: Simple parsing, Previous: ASN.1 syntax, Up: ASN.1 structure handling [Contents][Index]
Consider this definition:
Example { 1 2 3 4 } DEFINITIONS EXPLICIT TAGS ::= BEGIN Group ::= SEQUENCE { id OBJECT IDENTIFIER, value Value } Value ::= SEQUENCE { value1 INTEGER, value2 BOOLEAN } END
The notation to access the ‘Group’ type of the ‘Example’ definition above is ‘Example.Group’ (as a NUL-terminated string.) Such strings are used in the functions described below.
Others examples:
Elements of structured types unnamed by the respective definition
receive the names ?1
, ?2
, and so on.
The ?LAST
name indicates the last element of a SET OF
or
SEQUENCE OF
.
Next: Library Notes, Previous: Naming, Up: ASN.1 structure handling [Contents][Index]
For simple types like OCTET STRING
the simple parsing functions listed
below may be used instead.
Next: Future developments, Previous: Simple parsing, Up: ASN.1 structure handling [Contents][Index]
The header file of this library is libtasn1.h.
The main type used in it is asn1_node
, and it’s used to store
the ASN.1 definitions and structures (instances).
The NULL
constant can be used for the variable
initialization. For example:
asn1_node definitions = NULL;
Some functions require an errorDescription
argument of type
char *
, pointing to a pre-allocated buffer of at least
ASN1_MAX_ERROR_DESCRIPTION_SIZE
bytes size (e.g., as in
‘char description[ASN1_MAX_ERROR_DESCRIPTION_SIZE];’).
ASN1_MAX_NAME_SIZE
is the maximum number of characters allowed
for an ASN.1 identifier.
Previous: Library Notes, Up: ASN.1 structure handling [Contents][Index]
REAL
type.
Next: Function reference, Previous: ASN.1 structure handling, Up: Top [Contents][Index]
• Invoking asn1Parser: | ||
• Invoking asn1Coding: | ||
• Invoking asn1Decoding: |
Next: Invoking asn1Coding, Up: Utilities [Contents][Index]
asn1Parser
reads a single file with ASN.1 definitions and
generates a
file with an array to use with libtasn1 functions.
Usage: asn1Parser [options] file Options: -h : shows the help message. -v : shows version information and exit. -c : checks the syntax only. -o file : output file. -n name : array name.
Next: Invoking asn1Decoding, Previous: Invoking asn1Parser, Up: Utilities [Contents][Index]
asn1Coding
generates a DER encoding from a file with ASN.1
definitions and another one with assignments.
The file with assignments must have this syntax:
InstanceName Asn1Definition nameString value nameString value ...
To specify the field of a CHOICE
to be used, specify its name
as a value to the CHOICE
element itself. Use ''
to
denote the root element itself.
(as in the example below.)
The output file is a binary file with the DER encoding.
Usage: asn1Coding [options] file1 file2 file1 : file with ASN1 definitions. file2 : file with assignments. Options: -h : shows the help message. -v : shows version information and exit. -c : checks the syntax only. -o file : output file.
For example, consider an ASN.1 definitions file as follows:
MYPKIX1 { } DEFINITIONS IMPLICIT TAGS ::= BEGIN OtherStruct := SEQUENCE { x INTEGER, y CHOICE { y1 INTEGER, y2 OCTET STRING }, } Dss-Sig-Value ::= SEQUENCE { r INTEGER, s INTEGER, other OtherStruct z INTEGER OPTIONAL, } END
And a assignments file as follows:
dp MYPKIX1.Dss-Sig-Value r 42 s 47 other.x 66 other.y y1 other.y.y1 15 z (NULL)
Running the command below will generate a assign.out file,
containing the DER encoding of PKIX1.Dss-Sig-Value
.
$ asn1Coding pkix.asn assign.asn1
If the root element is of the CHOICE
type, the assignment file
may be like (using the types defined in pkix.asn):
elt PKIX1Implicit88.GeneralName '' dNSName dNSName example.org
Previous: Invoking asn1Coding, Up: Utilities [Contents][Index]
asn1Decoding
generates an ASN.1 structure from a file with
ASN.1
definitions and a binary file with a DER encoding.
Usage: asn1Decoding [options] file1 file2 type file1 : file with ASN1 definitions. file2 : binary file with a DER encoding. type : ASN1 definition name. Options: -h : shows the help message. -v : shows version information and exit. -o file : output file.
For example, after generating the assign.out file from the
example section of the asn1Coding
command above, the
following
invocation will decode the DER data.
$ asn1Decoding pkix.asn assign.out PKIX1.Dss-Sig-Value
Next: Copying Information, Previous: Utilities, Up: Top [Contents][Index]
• ASN.1 schema functions: | ||
• ASN.1 field functions: | ||
• DER functions: | ||
• Error handling functions: | ||
• Auxilliary functions: |
Next: ASN.1 field functions, Up: Function reference [Contents][Index]
file: specify the path and the name of file that contains ASN.1 declarations.
definitions: return the pointer to the structure created from "file" ASN.1 declarations.
error_desc: return the error description or an empty string if success.
Function used to start the parse algorithm. Creates the structures
needed to manage the definitions included in file
file.
Returns: ASN1_SUCCESS
if the file has a correct syntax and every
identifier is known, ASN1_ELEMENT_NOT_EMPTY
if definitions
not
NULL
, ASN1_FILE_NOT_FOUND
if an error occurred while
opening file
, ASN1_SYNTAX_ERROR
if the syntax is not
correct, ASN1_IDENTIFIER_NOT_FOUND
if in the file there is an
identifier that is not defined, ASN1_NAME_TOO_LONG
if in the
file there is an identifier whith more than ASN1_MAX_NAME_SIZE
characters.
inputFileName: specify the path and the name of file that contains ASN.1 declarations.
outputFileName: specify the path and the name of file that will contain the C vector definition.
vectorName: specify the name of the C vector.
error_desc: return the error description or an empty string if success.
Function that generates a C structure from an ASN1 file. Creates a
file containing a C vector to use to manage the definitions
included in inputFileName
file. If inputFileName
is
"/aa/bb/xx.yy" and outputFileName
is NULL
, the file created is
"/aa/bb/xx_asn1_tab.c". If vectorName
is NULL
the vector name
will be "xx_asn1_tab".
Returns: ASN1_SUCCESS
if the file has a correct syntax and every
identifier is known, ASN1_FILE_NOT_FOUND
if an error occurred
while opening inputFileName
, ASN1_SYNTAX_ERROR
if the syntax is
not correct, ASN1_IDENTIFIER_NOT_FOUND
if in the file there is
an identifier that is not defined, ASN1_NAME_TOO_LONG
if in the
file there is an identifier whith more than ASN1_MAX_NAME_SIZE
characters.
Next: DER functions, Previous: ASN.1 schema functions, Up: Function reference [Contents][Index]
array: specify the array that contains ASN.1 declarations
definitions: return the pointer to the structure created by *ARRAY ASN.1 declarations
errorDescription: return the error description.
Creates the structures needed to manage the ASN.1 definitions.
array
is a vector created by asn1_parser2array()
.
Returns: ASN1_SUCCESS
if structure was created correctly,
ASN1_ELEMENT_NOT_EMPTY
if * definitions
not NULL,
ASN1_IDENTIFIER_NOT_FOUND
if in the file there is an identifier
that is not defined (see errorDescription
for more information),
ASN1_ARRAY_ERROR
if the array pointed by array
is wrong.
structure: pointer to the structure that you want to delete.
Deletes the structure * structure
. At the end, * structure
is set
to NULL.
Returns: ASN1_SUCCESS
if successful, ASN1_ELEMENT_NOT_FOUND
if
* structure
was NULL.
structure: pointer to the structure that you want to delete.
flags: additional flags (see ASN1_DELETE_FLAG
)
Deletes the structure * structure
. At the end, * structure
is set
to NULL.
Returns: ASN1_SUCCESS
if successful, ASN1_ELEMENT_NOT_FOUND
if
* structure
was NULL.
structure: pointer to the structure that contains the element you want to delete.
element_name: element’s name you want to delete.
Deletes the element named * element_name
inside * structure
.
Returns: ASN1_SUCCESS
if successful, ASN1_ELEMENT_NOT_FOUND
if
the element_name
was not found.
definitions: pointer to the structure returned by "parser_asn1" function
source_name: the name of the type of the new structure (must be inside p_structure).
element: pointer to the structure created.
Creates a structure of type source_name
. Example using
"pkix.asn":
rc = asn1_create_element(cert_def, "PKIX1.Certificate", certptr);
Returns: ASN1_SUCCESS
if creation OK, ASN1_ELEMENT_NOT_FOUND
if
source_name
is not known.
out: pointer to the output file (e.g. stdout).
structure: pointer to the structure that you want to visit.
name: an element of the structure
mode: specify how much of the structure to print, can be
ASN1_PRINT_NAME
, ASN1_PRINT_NAME_TYPE
,
ASN1_PRINT_NAME_TYPE_VALUE
, or ASN1_PRINT_ALL
.
Prints on the out
file descriptor the structure’s tree starting
from the name
element inside the structure structure
.
element: pointer to the root of an ASN1 structure.
name: the name of a sub-structure of ROOT.
num: pointer to an integer where the result will be stored
Counts the number of elements of a sub-structure called NAME with names equal to "?1","?2", ...
Returns: ASN1_SUCCESS
if successful, ASN1_ELEMENT_NOT_FOUND
if
name
is not known, ASN1_GENERIC_ERROR
if pointer num
is NULL
.
definitions: ASN1 definitions
oidValue: value of the OID to search (e.g. "1.2.3.4").
Search the structure that is defined just after an OID definition.
Returns: NULL
when oidValue
not found, otherwise the pointer to a
constant string that contains the element name defined just after
the OID.
dst: Destination asn1 node.
dst_name: Field name in destination node.
src: Source asn1 node.
src_name: Field name in source node.
Create a deep copy of a asn1_node variable. That
function requires dst
to be expanded using asn1_create_element()
.
Returns: Return ASN1_SUCCESS
on success.
src: Source asn1 node.
src_name: Field name in source node.
Create a deep copy of a asn1_node variable. This function will return an exact copy of the provided structure.
Returns: Return NULL
on failure.
node_root: pointer to a structure
name: the name of the element inside the structure that you want to set.
ivalue: vector used to specify the value to set. If len is >0, VALUE must be a two’s complement form integer. if len=0 *VALUE must be a null terminated string with an integer value.
len: number of bytes of *value to use to set the value: value[0]..value[len-1] or 0 if value is a null terminated string
Set the value of one element inside a structure.
If an element is OPTIONAL and you want to delete it, you must use the value=NULL and len=0. Using "pkix.asn":
result=asn1_write_value(cert, "tbsCertificate.issuerUniqueID", NULL, 0);
Description for each type:
INTEGER: VALUE must contain a two’s complement form integer.
value[0]=0xFF , len=1 -> integer=-1. value[0]=0xFF value[1]=0xFF , len=2 -> integer=-1. value[0]=0x01 , len=1 -> integer= 1. value[0]=0x00 value[1]=0x01 , len=2 -> integer= 1. value="123" , len=0 -> integer= 123.
ENUMERATED: As INTEGER (but only with not negative numbers).
BOOLEAN: VALUE must be the null terminated string "TRUE" or "FALSE" and LEN != 0.
value="TRUE" , len=1 -> boolean=TRUE. value="FALSE" , len=1 -> boolean=FALSE.
OBJECT IDENTIFIER: VALUE must be a null terminated string with each number separated by a dot (e.g. "1.2.3.543.1"). LEN != 0.
value="1 2 840 10040 4 3" , len=1 -> OID=dsa-with-sha.
UTCTime: VALUE must be a null terminated string in one of these formats: "YYMMDDhhmmssZ", "YYMMDDhhmmssZ", "YYMMDDhhmmss+hh’mm’", "YYMMDDhhmmss-hh’mm’", "YYMMDDhhmm+hh’mm’", or "YYMMDDhhmm-hh’mm’". LEN != 0.
value="9801011200Z" , len=1 -> time=Jannuary 1st, 1998 at 12h 00m Greenwich Mean Time
GeneralizedTime: VALUE must be in one of this format: "YYYYMMDDhhmmss.sZ", "YYYYMMDDhhmmss.sZ", "YYYYMMDDhhmmss.s+hh’mm’", "YYYYMMDDhhmmss.s-hh’mm’", "YYYYMMDDhhmm+hh’mm’", or "YYYYMMDDhhmm-hh’mm’" where ss.s indicates the seconds with any precision like "10.1" or "01.02". LEN != 0
value="2001010112001.12-0700" , len=1 -> time=Jannuary 1st, 2001 at 12h 00m 01.12s Pacific Daylight Time
OCTET STRING: VALUE contains the octet string and LEN is the number of octets.
value="$\backslash$x01$\backslash$x02$\backslash$x03" , len=3 -> three bytes octet string
GeneralString: VALUE contains the generalstring and LEN is the number of octets.
value="$\backslash$x01$\backslash$x02$\backslash$x03" , len=3 -> three bytes generalstring
BIT STRING: VALUE contains the bit string organized by bytes and LEN is the number of bits.
value="$\backslash$xCF" , len=6 -> bit string="110011" (six bits)
CHOICE: if NAME indicates a choice type, VALUE must specify one of the alternatives with a null terminated string. LEN != 0. Using "pkix.asn"\:
result=asn1_write_value(cert, "certificate1.tbsCertificate.subject", "rdnSequence", 1);
ANY: VALUE indicates the der encoding of a structure. LEN != 0.
SEQUENCE OF: VALUE must be the null terminated string "NEW" and LEN != 0. With this instruction another element is appended in the sequence. The name of this element will be "?1" if it’s the first one, "?2" for the second and so on.
Using "pkix.asn"\:
result=asn1_write_value(cert, "certificate1.tbsCertificate.subject.rdnSequence", "NEW", 1);
SET OF: the same as SEQUENCE OF. Using "pkix.asn":
result=asn1_write_value(cert, "tbsCertificate.subject.rdnSequence.?LAST", "NEW", 1);
Returns: ASN1_SUCCESS
if the value was set,
ASN1_ELEMENT_NOT_FOUND
if name
is not a valid element, and
ASN1_VALUE_NOT_VALID
if ivalue
has a wrong format.
root: pointer to a structure.
name: the name of the element inside a structure that you want to read.
ivalue: vector that will contain the element’s content, must be a
pointer to memory cells already allocated (may be NULL
).
len: number of bytes of *value: value[0]..value[len-1]. Initialy holds the sizeof value.
Returns the value of one element inside a structure.
If an element is OPTIONAL and this returns
ASN1_ELEMENT_NOT_FOUND
, it means that this element wasn’t present
in the der encoding that created the structure. The first element
of a SEQUENCE_OF or SET_OF is named "?1". The second one "?2" and
so on. If the root
provided is a node to specific sequence element,
then the keyword "?CURRENT" is also acceptable and indicates the
current sequence element of this node.
Note that there can be valid values with length zero. In these case
this function will succeed and len
will be zero.
INTEGER: VALUE will contain a two’s complement form integer.
integer=-1 -> value[0]=0xFF , len=1. integer=1 -> value[0]=0x01 , len=1.
ENUMERATED: As INTEGER (but only with not negative numbers).
BOOLEAN: VALUE will be the null terminated string "TRUE" or "FALSE" and LEN=5 or LEN=6.
OBJECT IDENTIFIER: VALUE will be a null terminated string with each number separated by a dot (i.e. "1.2.3.543.1").
LEN = strlen(VALUE)+1
UTCTime: VALUE will be a null terminated string in one of these formats: "YYMMDDhhmmss+hh’mm’" or "YYMMDDhhmmss-hh’mm’". LEN=strlen(VALUE)+1.
GeneralizedTime: VALUE will be a null terminated string in the same format used to set the value.
OCTET STRING: VALUE will contain the octet string and LEN will be the number of octets.
GeneralString: VALUE will contain the generalstring and LEN will be the number of octets.
BIT STRING: VALUE will contain the bit string organized by bytes and LEN will be the number of bits.
CHOICE: If NAME indicates a choice type, VALUE will specify the alternative selected.
ANY: If NAME indicates an any type, VALUE will indicate the DER encoding of the structure actually used.
Returns: ASN1_SUCCESS
if value is returned,
ASN1_ELEMENT_NOT_FOUND
if name
is not a valid element,
ASN1_VALUE_NOT_FOUND
if there isn’t any value for the element
selected, and ASN1_MEM_ERROR
if The value vector isn’t big enough
to store the result, and in this case len
will contain the number of
bytes needed. On the occasion that the stored data are of zero-length
this function may return ASN1_SUCCESS
even if the provided len
is zero.
root: pointer to a structure.
name: the name of the element inside a structure that you want to read.
ivalue: vector that will contain the element’s content, must be a
pointer to memory cells already allocated (may be NULL
).
len: number of bytes of *value: value[0]..value[len-1]. Initialy holds the sizeof value.
etype: The type of the value read (ASN1_ETYPE)
Returns the type and value of one element inside a structure.
If an element is OPTIONAL and this returns
ASN1_ELEMENT_NOT_FOUND
, it means that this element wasn’t present
in the der encoding that created the structure. The first element
of a SEQUENCE_OF or SET_OF is named "?1". The second one "?2" and
so on. If the root
provided is a node to specific sequence element,
then the keyword "?CURRENT" is also acceptable and indicates the
current sequence element of this node.
Note that there can be valid values with length zero. In these case
this function will succeed and len
will be zero.
INTEGER: VALUE will contain a two’s complement form integer.
integer=-1 -> value[0]=0xFF , len=1. integer=1 -> value[0]=0x01 , len=1.
ENUMERATED: As INTEGER (but only with not negative numbers).
BOOLEAN: VALUE will be the null terminated string "TRUE" or "FALSE" and LEN=5 or LEN=6.
OBJECT IDENTIFIER: VALUE will be a null terminated string with each number separated by a dot (i.e. "1.2.3.543.1").
LEN = strlen(VALUE)+1
UTCTime: VALUE will be a null terminated string in one of these formats: "YYMMDDhhmmss+hh’mm’" or "YYMMDDhhmmss-hh’mm’". LEN=strlen(VALUE)+1.
GeneralizedTime: VALUE will be a null terminated string in the same format used to set the value.
OCTET STRING: VALUE will contain the octet string and LEN will be the number of octets.
GeneralString: VALUE will contain the generalstring and LEN will be the number of octets.
BIT STRING: VALUE will contain the bit string organized by bytes and LEN will be the number of bits.
CHOICE: If NAME indicates a choice type, VALUE will specify the alternative selected.
ANY: If NAME indicates an any type, VALUE will indicate the DER encoding of the structure actually used.
Returns: ASN1_SUCCESS
if value is returned,
ASN1_ELEMENT_NOT_FOUND
if name
is not a valid element,
ASN1_VALUE_NOT_FOUND
if there isn’t any value for the element
selected, and ASN1_MEM_ERROR
if The value vector isn’t big enough
to store the result, and in this case len
will contain the number of
bytes needed. On the occasion that the stored data are of zero-length
this function may return ASN1_SUCCESS
even if the provided len
is zero.
root: pointer to a structure
name: the name of the element inside a structure.
tagValue: variable that will contain the TAG value.
classValue: variable that will specify the TAG type.
Returns the TAG and the CLASS of one element inside a structure.
CLASS can have one of these constants: ASN1_CLASS_APPLICATION
,
ASN1_CLASS_UNIVERSAL
, ASN1_CLASS_PRIVATE
or
ASN1_CLASS_CONTEXT_SPECIFIC
.
Returns: ASN1_SUCCESS
if successful, ASN1_ELEMENT_NOT_FOUND
if
name
is not a valid element.
node: pointer to a node.
data: a point to a asn1_data_node_st
Returns the value a data node inside a asn1_node structure. The data returned should be handled as constant values.
Returns: ASN1_SUCCESS
if the node exists.
Next: Error handling functions, Previous: ASN.1 field functions, Up: Function reference [Contents][Index]
len: value to convert.
der: buffer to hold the returned encoding (may be NULL
).
der_len: number of meaningful bytes of ANS (der[0]..der[der_len-1]).
Creates the DER encoding of the provided length value.
The der
buffer must have enough room for the output. The maximum
length this function will encode is ASN1_MAX_LENGTH_SIZE
.
To know the size of the DER encoding use a NULL
value for der
.
str: the input data.
str_len: STR length (str[0]..str[*str_len-1]).
der: encoded string returned.
der_len: number of meaningful bytes of DER (der[0]..der[der_len-1]).
Creates a length-value DER encoding for the input data.
The DER encoding of the input data will be placed in the der
variable.
Note that the OCTET STRING tag is not included in the output.
This function does not return any value because it is expected
that der_len
will contain enough bytes to store the string
plus the DER encoding. The DER encoding size can be obtained using
asn1_length_der()
.
etype: The type of the string to be encoded (ASN1_ETYPE_)
str: the string data.
str_len: the string length
tl: the encoded tag and length
tl_len: the bytes of the tl
field
Creates the DER encoding for various simple ASN.1 types like strings etc.
It stores the tag and length in tl
, which should have space for at least
ASN1_MAX_TL_SIZE
bytes. Initially tl_len
should contain the size of tl
.
The complete DER encoding should consist of the value in tl
appended
with the provided str
.
Returns: ASN1_SUCCESS
if successful or an error value.
str: BIT string.
bit_len: number of meaningful bits in STR.
der: string returned.
der_len: number of meaningful bytes of DER (der[0]..der[ans_len-1]).
Creates a length-value DER encoding for the input data
as it would have been for a BIT STRING.
The DER encoded data will be copied in der
.
Note that the BIT STRING tag is not included in the output.
This function does not return any value because it is expected
that der_len
will contain enough bytes to store the string
plus the DER encoding. The DER encoding size can be obtained using
asn1_length_der()
.
element: pointer to an ASN1 element
name: the name of the structure you want to encode (it must be inside *POINTER).
ider: vector that will contain the DER encoding. DER must be a pointer to memory cells already allocated.
len: number of bytes of * ider
: ider
[0].. ider
[len-1], Initialy
holds the sizeof of der vector.
ErrorDescription: return the error description or an empty string if success.
Creates the DER encoding for the NAME structure (inside *POINTER structure).
Returns: ASN1_SUCCESS
if DER encoding OK, ASN1_ELEMENT_NOT_FOUND
if name
is not a valid element, ASN1_VALUE_NOT_FOUND
if there
is an element without a value, ASN1_MEM_ERROR
if the ider
vector isn’t big enough and in this case len
will contain the
length needed.
der: DER data to decode.
der_len: Length of DER data to decode.
len: Output variable containing the length of the DER length field.
Extract a length field from DER data.
Returns: Return the decoded length value, or -1 on indefinite
length, or -2 when the value was too big to fit in a int, or -4
when the decoded length value plus len
would exceed der_len
.
der: DER data to decode.
der_len: Length of DER data to decode.
cls: Output variable containing decoded class.
len: Output variable containing the length of the DER TAG data.
tag: Output variable containing the decoded tag (may be NULL
).
Decode the class and TAG from DER code.
Returns: Returns ASN1_SUCCESS
on success, or an error.
ber: BER data to decode.
ber_len: Length of BER data to decode.
len: Output variable containing the length of the BER length field.
Extract a length field from BER data. The difference to
asn1_get_length_der()
is that this function will return a length
even if the value has indefinite encoding.
Returns: Return the decoded length value, or negative value when the value was too big.
Since: 2.0
der: DER data to decode containing the OCTET SEQUENCE.
der_len: The length of the der
data to decode.
ret_len: Output variable containing the encoded length of the DER data.
str: Pre-allocated output buffer to put decoded OCTET SEQUENCE in.
str_size: Length of pre-allocated output buffer.
str_len: Output variable containing the length of the contents of the OCTET SEQUENCE.
Extract an OCTET SEQUENCE from DER data. Note that this function expects the DER data past the tag field, i.e., the length and content octets.
Returns: Returns ASN1_SUCCESS
on success, or an error.
der: DER data to decode containing the OBJECT IDENTIFIER
der_len: Length of DER data to decode.
ret_len: Output variable containing the length of the DER data.
str: Pre-allocated output buffer to put the textual object id in.
str_size: Length of pre-allocated output buffer.
Converts a DER encoded object identifier to its textual form. This function expects the DER object identifier without the tag.
Returns: ASN1_SUCCESS
on success, or an error.
der: DER data to decode containing the BIT SEQUENCE.
der_len: Length of DER data to decode.
ret_len: Output variable containing the length of the DER data.
str: Pre-allocated output buffer to put decoded BIT SEQUENCE in.
str_size: Length of pre-allocated output buffer.
bit_len: Output variable containing the size of the BIT SEQUENCE.
Extract a BIT SEQUENCE from DER data.
Returns: ASN1_SUCCESS
on success, or an error.
element: pointer to an ASN1 structure.
ider: vector that contains the DER encoding.
max_ider_len: pointer to an integer giving the information about the
maximal number of bytes occupied by * ider
. The real size of the DER
encoding is returned through this pointer.
flags: flags controlling the behaviour of the function.
errorDescription: null-terminated string contains details when an error occurred.
Fill the structure * element
with values of a DER encoding string. The
structure must just be created with function asn1_create_element()
.
If ASN1_DECODE_FLAG_ALLOW_PADDING
flag is set then the function will ignore
padding after the decoded DER data. Upon a successful return the value of
* max_ider_len
will be set to the number of bytes decoded.
If ASN1_DECODE_FLAG_STRICT_DER
flag is set then the function will
not decode any BER-encoded elements.
Returns: ASN1_SUCCESS
if DER encoding OK, ASN1_ELEMENT_NOT_FOUND
if ELEMENT
is NULL
, and ASN1_TAG_ERROR
or
ASN1_DER_ERROR
if the der encoding doesn’t match the structure
name (* ELEMENT
deleted).
element: pointer to an ASN1 structure.
ider: vector that contains the DER encoding.
ider_len: number of bytes of * ider
: ider
[0].. ider
[len-1].
errorDescription: null-terminated string contains details when an error occurred.
Fill the structure * element
with values of a DER encoding
string. The structure must just be created with function
asn1_create_element()
.
Note that the * element
variable is provided as a pointer for
historical reasons.
Returns: ASN1_SUCCESS
if DER encoding OK, ASN1_ELEMENT_NOT_FOUND
if ELEMENT
is NULL
, and ASN1_TAG_ERROR
or
ASN1_DER_ERROR
if the der encoding doesn’t match the structure
name (* ELEMENT
deleted).
structure: pointer to an ASN1 structure
elementName: name of the element to fill
ider: vector that contains the DER encoding of the whole structure.
len: number of bytes of *der: der[0]..der[len-1]
errorDescription: null-terminated string contains details when an error occurred.
Fill the element named ELEMENTNAME
with values of a DER encoding
string. The structure must just be created with function
asn1_create_element()
. The DER vector must contain the encoding
string of the whole STRUCTURE
. If an error occurs during the
decoding procedure, the * STRUCTURE
is deleted and set equal to
NULL
.
This function is deprecated and may just be an alias to asn1_der_decoding
in future versions. Use asn1_der_decoding()
instead.
Returns: ASN1_SUCCESS
if DER encoding OK, ASN1_ELEMENT_NOT_FOUND
if ELEMENT is NULL
or elementName
== NULL, and
ASN1_TAG_ERROR
or ASN1_DER_ERROR
if the der encoding doesn’t
match the structure structure
(*ELEMENT deleted).
element: pointer to an ASN1 element
ider: vector that contains the DER encoding.
ider_len: number of bytes of * ider
: ider
[0].. ider
[len-1]
name_element: an element of NAME structure.
start: the position of the first byte of NAME_ELEMENT decoding
( ider
[*start])
end: the position of the last byte of NAME_ELEMENT decoding
( ider
[*end])
Find the start and end point of an element in a DER encoding
string. I mean that if you have a der encoding and you have already
used the function asn1_der_decoding()
to fill a structure, it may
happen that you want to find the piece of string concerning an
element of the structure.
One example is the sequence "tbsCertificate" inside an X509 certificate.
Note that since libtasn1 3.7 the ider
and ider_len
parameters
can be omitted, if the element is already decoded using asn1_der_decoding()
.
Returns: ASN1_SUCCESS
if DER encoding OK, ASN1_ELEMENT_NOT_FOUND
if ELEMENT is asn1_node
EMPTY or name_element
is not a valid
element, ASN1_TAG_ERROR
or ASN1_DER_ERROR
if the der encoding
doesn’t match the structure ELEMENT.
definitions: ASN1 definitions
element: pointer to an ASN1 structure
Expands every "ANY DEFINED BY" element of a structure created from a DER decoding process (asn1_der_decoding function). The element ANY must be defined by an OBJECT IDENTIFIER. The type used to expand the element ANY is the first one following the definition of the actual value of the OBJECT IDENTIFIER.
Returns: ASN1_SUCCESS
if Substitution OK, ASN1_ERROR_TYPE_ANY
if
some "ANY DEFINED BY" element couldn’t be expanded due to a
problem in OBJECT_ID -> TYPE association, or other error codes
depending on DER decoding.
definitions: ASN1 definitions
element: pointer to an ASN1 structure
octetName: name of the OCTECT STRING field to expand.
objectName: name of the OBJECT IDENTIFIER field to use to define the type for expansion.
Expands an "OCTET STRING" element of a structure created from a DER
decoding process (the asn1_der_decoding()
function). The type used
for expansion is the first one following the definition of the
actual value of the OBJECT IDENTIFIER indicated by OBJECTNAME.
Returns: ASN1_SUCCESS
if substitution OK, ASN1_ELEMENT_NOT_FOUND
if objectName
or octetName
are not correct,
ASN1_VALUE_NOT_VALID
if it wasn’t possible to find the type to
use for expansion, or other errors depending on DER decoding.
etype: The type of the string to be encoded (ASN1_ETYPE_)
der: the encoded string
_der_len: the bytes of the encoded string
str: a pointer to the data
str_len: the length of the data
Decodes a simple DER encoded type (e.g. a string, which is not constructed).
The output is a pointer inside the der
.
Returns: ASN1_SUCCESS
if successful or an error value.
etype: The type of the string to be encoded (ASN1_ETYPE_)
der: the encoded string
_der_len: the bytes of the encoded string
str: a pointer to the data
str_len: the length of the data
ber_len: the total length occupied by BER (may be NULL
)
Decodes a BER encoded type. The output is an allocated value of the data. This decodes BER STRINGS only. Other types are decoded as DER.
Returns: ASN1_SUCCESS
if successful or an error value.
Next: Auxilliary functions, Previous: DER functions, Up: Function reference [Contents][Index]
error: is an error returned by a libtasn1 function.
Prints a string to stderr with a description of an error. This
function is like perror()
. The only difference is that it accepts
an error returned by a libtasn1 function.
Since: 1.6
error: is an error returned by a libtasn1 function.
Returns a string with a description of an error. This function is similar to strerror. The only difference is that it accepts an error (number) returned by a libtasn1 function.
Returns: Pointer to static zero-terminated string describing error code.
Since: 1.6
Previous: Error handling functions, Up: Function reference [Contents][Index]
pointer: NODE_ASN element pointer.
name: null terminated string with the element’s name to find.
Searches for an element called name
starting from pointer
. The
name is composed by different identifiers separated by dots. When
* pointer
has a name, the first identifier must be the name of
* pointer
, otherwise it must be the name of one child of * pointer
.
Returns: the search result, or NULL
if not found.
req_version: Required version number, or NULL
.
Check that the version of the library is at minimum the
requested one and return the version string; return NULL
if the
condition is not satisfied. If a NULL
is passed to this function,
no check is done, but the version string is simply returned.
See ASN1_VERSION
for a suitable req_version
string.
Returns: Version string of run-time library, or NULL
if the
run-time library does not meet the required version number.
Next: Concept Index, Previous: Function reference, Up: Top [Contents][Index]
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Up: Copying Information [Contents][Index]
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