You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
tdepim/certmanager/lib/cryptplug.h

954 lines
36 KiB

/*
this is a C++-ification of:
CRYPTPLUG - an independent cryptography plug-in API
Copyright (C) 2001,2004 Klar<EFBFBD>lvdalens Datakonsult AB
CRYPTPLUG is free software; you can redistribute it and/or modify
it under the terms of GNU General Public License as published by
the Free Software Foundation; version 2 of the License.
CRYPTPLUG is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
*/
#ifndef CRYPTPLUG_H
#define CRYPTPLUG_H
#include <stdlib.h>
#include <gpgmepp/context.h>
#include <gpgme.h> // need it for gpgme_protocol_t :(
#include <tdemacros.h>
namespace GpgME {
class ImportResult;
}
/*! \file cryptplug.h
\brief Common API header for CRYPTPLUG.
CRYPTPLUG is an independent cryptography plug-in API
developed for Sphinx-enabeling KMail and Mutt.
CRYPTPLUG was designed for the Aegypten project, but it may
be used by 3rd party developers as well to design pluggable
crypto backends for the above mentioned MUAs.
\note All string parameters appearing in this API are to be
interpreted as UTF-8 encoded.
\see pgpplugin.c
\see gpgplugin.c
*/
/*! \defgroup groupGeneral Loading and Unloading the Plugin, General Functionality
The functions in this section are used for loading and
unloading plugins. Note that the actual locating of the plugin
and the loading and unloading of the dynamic library is not
covered here; this is MUA-specific code for which support code
might already exist in the programming environments.
*/
/*! \defgroup groupDisplay Graphical Display Functionality
The functions in this section return stationery that the
MUAs can use in order to display security functionality
graphically. This can be toolbar icons, shortcuts, tooltips,
etc. Not all MUAs will use all this functionality.
*/
/*! \defgroup groupConfig Configuration Support
The functions in this section provide the necessary
functionality to configure the security functionality as well
as to query configuration settings. Since all configuration
settings will not be saved with the plugin, but rather with
the MUA, there are also functions to set configuration
settings programmatically; these will be used on startup of
the plugin when the MUA transfers the configuration values it
has read into the plugin. Usually, the functions to query and
set the configuration values are not needed for anything but
saving to and restoring from configuration files.
*/
/*! \defgroup groupConfigSign Signature Configuration
\ingroup groupConfig
The functions in this section provide the functionality
to configure signature handling and set and query the
signature configuration.
*/
/*! \defgroup groupConfigCrypt Encryption Configuration
\ingroup groupConfig
The functions in this section provide the functionality
to configure encryption handling and set and query the
encryption configuration.
\note Whenever the term <b> encryption</b> is used here,
it is supposed to mean both encryption and decryption,
unless otherwise specified.
*/
/*! \defgroup groupConfigDir Directory Service Configuration
\ingroup groupConfig
This section contains messages for configuring the
directory service.
*/
/*! \defgroup groupCertHand Certificate Handling
The following methods are used to maintain and query certificates.
*/
/*! \defgroup groupSignCryptAct Signing and Encrypting Actions
This section describes methods and structures
used for signing and/or encrypting your mails.
*/
/*! \defgroup groupSignAct Signature Actions
\ingroup groupSignCryptAct
This section describes methods that are used for working
with signatures.
*/
/*! \defgroup groupCryptAct Encryption and Decryption
\ingroup groupSignCryptAct
The following methods are used to encrypt and decrypt
email messages.
*/
/*! \defgroup groupCertAct Certificate Handling Actions
The functions in this section provide local certificate management.
*/
/*! \defgroup groupCRLAct CRL Handling Actions
This section describes functions for managing CRLs.
*/
/*! \defgroup groupAdUsoInterno Important functions to be used by plugin implementors ONLY.
This section describes functions that have to be used by
plugin implementors but should not be used by plugin users
directly.
If you are not planning to write your own cryptography
plugin <b>you should ignore this</b> section!
*/
/*! \defgroup certList Certificate Info listing functions
*/
typedef enum {
Feature_undef = 0,
Feature_SignMessages = 1,
Feature_VerifySignatures = 2,
Feature_EncryptMessages = 3,
Feature_DecryptMessages = 4,
Feature_SendCertificates = 5,
Feature_WarnSignCertificateExpiry = 6,
Feature_WarnSignEmailNotInCertificate = 7,
Feature_PinEntrySettings = 8,
Feature_StoreMessagesWithSigs = 9,
Feature_EncryptionCRLs = 10,
Feature_WarnEncryptCertificateExpiry = 11,
Feature_WarnEncryptEmailNotInCertificate = 12,
Feature_StoreMessagesEncrypted = 13,
Feature_CheckCertificatePath = 14,
Feature_CertificateDirectoryService = 15,
Feature_CRLDirectoryService = 16,
Feature_CertificateInfo = 17
} Feature;
/* dummy values */
typedef enum {
PinRequest_undef = 0,
PinRequest_Always = 1,
PinRequest_WhenAddingCerts = 2,
PinRequest_AlwaysWhenSigning = 3,
PinRequest_OncePerSession = 4,
PinRequest_AfterMinutes = 5
} PinRequests;
typedef enum {
SignatureCompoundMode_undef = 0,
SignatureCompoundMode_Opaque = 1,
SignatureCompoundMode_Detached = 2
} SignatureCompoundMode;
typedef enum {
SendCert_undef = 0,
SendCert_DontSend = 1,
SendCert_SendOwn = 2,
SendCert_SendChainWithoutRoot = 3,
SendCert_SendChainWithRoot = 4
} SendCertificates;
typedef enum {
SignAlg_undef = 0,
SignAlg_SHA1 = 1
} SignatureAlgorithm;
typedef enum {
EncryptAlg_undef = 0,
EncryptAlg_RSA = 1,
EncryptAlg_SHA1 = 2,
EncryptAlg_TripleDES = 3
} EncryptionAlgorithm;
typedef enum {
SignEmail_undef = 0,
SignEmail_SignAll = 1,
SignEmail_Ask = 2,
SignEmail_DontSign = 3
} SignEmail;
typedef enum {
EncryptEmail_undef = 0,
EncryptEmail_EncryptAll = 1,
EncryptEmail_Ask = 2,
EncryptEmail_DontEncrypt = 3
} EncryptEmail;
typedef enum {
CertSrc_undef = 0,
CertSrc_Server = 1,
CertSrc_Local = 2,
CertSrc_ServerLocal = CertSrc_Server | CertSrc_Local
} CertificateSource;
/*! \ingroup groupSignAct
\brief Flags used to compose the SigStatusFlags value.
This status flags are used to compose the SigStatusFlags value
returned in \c SignatureMetaDataExtendedInfo after trying to
verify a signed message part's signature status.
The normal flags may <b>not</b> be used together with the
special SigStat_NUMERICAL_CODE flag. When finding the special
SigStat_NUMERICAL_CODE flag in a SigStatusFlags value you
can obtain the respective error code number by substracting
the SigStatusFlags value by SigStat_NUMERICAL_CODE: this is
used to transport special status information NOT matching
any of the normal predefined status codes.
\note to PlugIn developers: Implementations of the CryptPlug API
should try to express their signature states by bit-wise OR'ing
the normal SigStatusFlags values. Using the SigStat_NUMERICAL_CODE
flag should only be used as for exceptional situations where no
other flag(s) could be used. By using the normal status flags your
PlugIn's users will be told an understandable description of the
status - when using (SigStat_NUMERICAL_CODE + internalCode) they
will only be shown the respective code number and have to look
into your PlugIn's manual to learn about it's meaning...
*/
enum {
SigStat_VALID = 0x0001, /* The signature is fully valid */
SigStat_GREEN = 0x0002, /* The signature is good. */
SigStat_RED = 0x0004, /* The signature is bad. */
SigStat_KEY_REVOKED = 0x0010, /* One key has been revoked. */
SigStat_KEY_EXPIRED = 0x0020, /* One key has expired. */
SigStat_SIG_EXPIRED = 0x0040, /* The signature has expired. */
SigStat_KEY_MISSING = 0x0080, /* Can't verify: key missing. */
SigStat_CRL_MISSING = 0x0100, /* CRL not available. */
SigStat_CRL_TOO_OLD = 0x0200, /* Available CRL is too old. */
SigStat_BAD_POLICY = 0x0400, /* A policy was not met. */
SigStat_SYS_ERROR = 0x0800, /* A system error occurred. */
SigStat_NUMERICAL_CODE = 0x8000 /* An other error occurred. */
};
typedef unsigned long SigStatusFlags;
class CryptPlugWrapper;
class TDE_EXPORT CryptPlug {
friend class CryptPlugWrapper;
protected:
CryptPlug();
virtual ~CryptPlug();
// these must be set by subclasses:
gpgme_protocol_t GPGMEPLUG_PROTOCOL;
GpgME::Context::Protocol mProtocol;
/* definitions for signing */
// 1. opaque signatures (only used for S/MIME)
int GPGMEPLUG_OPA_SIGN_INCLUDE_CLEARTEXT;
int GPGMEPLUG_OPA_SIGN_MAKE_MIME_OBJECT;
int GPGMEPLUG_OPA_SIGN_MAKE_MULTI_MIME;
const char * GPGMEPLUG_OPA_SIGN_CTYPE_MAIN;
const char * GPGMEPLUG_OPA_SIGN_CDISP_MAIN;
const char * GPGMEPLUG_OPA_SIGN_CTENC_MAIN;
const char * GPGMEPLUG_OPA_SIGN_CTYPE_VERSION;
const char * GPGMEPLUG_OPA_SIGN_CDISP_VERSION;
const char * GPGMEPLUG_OPA_SIGN_CTENC_VERSION;
const char * GPGMEPLUG_OPA_SIGN_BTEXT_VERSION;
const char * GPGMEPLUG_OPA_SIGN_CTYPE_CODE;
const char * GPGMEPLUG_OPA_SIGN_CDISP_CODE;
const char * GPGMEPLUG_OPA_SIGN_CTENC_CODE;
const char * GPGMEPLUG_OPA_SIGN_FLAT_PREFIX;
const char * GPGMEPLUG_OPA_SIGN_FLAT_SEPARATOR;
const char * GPGMEPLUG_OPA_SIGN_FLAT_POSTFIX;
// 2. detached signatures (used for S/MIME and for OpenPGP)
int GPGMEPLUG_DET_SIGN_INCLUDE_CLEARTEXT;
int GPGMEPLUG_DET_SIGN_MAKE_MIME_OBJECT;
int GPGMEPLUG_DET_SIGN_MAKE_MULTI_MIME;
const char * GPGMEPLUG_DET_SIGN_CTYPE_MAIN;
const char * GPGMEPLUG_DET_SIGN_CDISP_MAIN;
const char * GPGMEPLUG_DET_SIGN_CTENC_MAIN;
const char * GPGMEPLUG_DET_SIGN_CTYPE_VERSION;
const char * GPGMEPLUG_DET_SIGN_CDISP_VERSION;
const char * GPGMEPLUG_DET_SIGN_CTENC_VERSION;
const char * GPGMEPLUG_DET_SIGN_BTEXT_VERSION;
const char * GPGMEPLUG_DET_SIGN_CTYPE_CODE;
const char * GPGMEPLUG_DET_SIGN_CDISP_CODE;
const char * GPGMEPLUG_DET_SIGN_CTENC_CODE;
const char * GPGMEPLUG_DET_SIGN_FLAT_PREFIX;
const char * GPGMEPLUG_DET_SIGN_FLAT_SEPARATOR;
const char * GPGMEPLUG_DET_SIGN_FLAT_POSTFIX;
// 3. common definitions for opaque and detached signing
int __GPGMEPLUG_SIGNATURE_CODE_IS_BINARY;
/* definitions for encoding */
int GPGMEPLUG_ENC_INCLUDE_CLEARTEXT;
int GPGMEPLUG_ENC_MAKE_MIME_OBJECT;
int GPGMEPLUG_ENC_MAKE_MULTI_MIME;
const char * GPGMEPLUG_ENC_CTYPE_MAIN;
const char * GPGMEPLUG_ENC_CDISP_MAIN;
const char * GPGMEPLUG_ENC_CTENC_MAIN;
const char * GPGMEPLUG_ENC_CTYPE_VERSION;
const char * GPGMEPLUG_ENC_CDISP_VERSION;
const char * GPGMEPLUG_ENC_CTENC_VERSION;
const char * GPGMEPLUG_ENC_BTEXT_VERSION;
const char * GPGMEPLUG_ENC_CTYPE_CODE;
const char * GPGMEPLUG_ENC_CDISP_CODE;
const char * GPGMEPLUG_ENC_CTENC_CODE;
const char * GPGMEPLUG_ENC_FLAT_PREFIX;
const char * GPGMEPLUG_ENC_FLAT_SEPARATOR;
const char * GPGMEPLUG_ENC_FLAT_POSTFIX;
int __GPGMEPLUG_ENCRYPTED_CODE_IS_BINARY;
// end-of(these must be set by subclasses)
public:
#define CRYPTPLUG_CERT_DOES_NEVER_EXPIRE 365000
#define CRYPTPLUG_ERR_WRONG_KEY_USAGE 0x7070
/*! \ingroup groupGeneral
\brief This function sets up all internal structures.
Plugins that need no initialization should provide an empty
implementation. The method returns \c true if the initialization was
successful and \c false otherwise. Before this function is called,
no other plugin functions should be called; the behavior is
undefined in this case.
\note This function <b>must</b> be implemented by each plug-in using
this API specification.
*/
bool initialize( void );
/*! \ingroup groupGeneral
\brief This function frees all internal structures.
Plugins that do not keep any internal structures should provide an
empty implementation. After this function has been called,
no other plugin functions should be called; the behavior is
undefined in this case.
\note This function <b>must</b> be implemented by each plug-in using
this API specification.
*/
//void deinitialize( void );
/*! \ingroup groupGeneral
\brief This function returns \c true if the
specified feature is available in the plugin, and
\c false otherwise.
Not all plugins will support all features; a complete Sphinx
implementation will support all features contained in the enum,
however.
\note This function <b>must</b> be implemented by each plug-in using
this API specification.
*/
bool hasFeature( ::Feature );
/*! \ingroup groupSignCryptAct
\brief Information record returned by signing and by encrypting
functions - this record should be used together with a
corresponding \c free_StructuringInfo() function call.
Use this information to compose a MIME object containing signed
and/or encrypted content (or to build a text frame around your
flat non-MIME message body, resp.)
<b>If</b> value returned in \c makeMimeObject is <b>TRUE</b> the
text strings returned in \c contentTypeMain and \c contentDispMain
and \c contentTEncMain (and, if required, \c content[..]Version and
\c bodyTextVersion and \c content[..]Sig) should be used to compose
a respective MIME object.<br>
If <b>FALSE</b> the texts returned in \c flatTextPrefix and
\c flatTextSeparator and \c flatTextPostfix are to be used instead.<br>
Allways <b>either</b> the \c content[..] and \c bodyTextVersion
parameters <b>or</b> the \c flatText[..] parameters are holding
valid data - never both of them may be used simultaneously
as plugins will just ignore the parameters not matching their
\c makeMimeObject setting.
When creating your MIME object please observe these common rules:
\li Parameters named \c contentType[..] and \c contentDisp[..] and
\c contentTEnc[..] will return the values for the respective MIME
headers 'Content-Type' and 'Content-Disposition' and
'Content-Transfer-Encoding'. The following applies to these parameters:
\li The relevant MIME part may <b>only</b> be created if the respective
\c contentType[..] parameter is holding a non-zero-length string. If the
\c contentType[..] parameter value is invalid or holding an empty string
the respective \c contentDisp[..] and \c contentTEnc[..] parameters
should be ignored.
\li If the respective \c contentDisp[..] or \c contentTEnc[..] parameter
is NULL or holding a zero-length string it is up to you whether you want
to add the relevant MIME header yourself, but since it in in the
responsibility of the plugin implementors to provide you with all
neccessary 'Content-[..]' header information you should <b>not need</b>
to define them if they are not returned by the signing or encrypting
function - otherwise this may be considered as a bug in the plugin and
you could report the missing MIME header information to the address
returned by the \c bugURL() function.
If \c makeMultiMime returns FALSE the \c contentTypeMain returned must
not be altered but used to specify a single part mime object holding the
code bloc, e.g. this is used for 'enveloped-data' single part MIME
objects. In this case you should ignore both the \c content[..]Version
and \c content[..]Code parameters.
If \c makeMultiMime returns TRUE also the following rules apply:
\li If \c includeCleartext is TRUE you should include the cleartext
as first part of our multipart MIME object, typically this is TRUE
when signing mails but FALSE when encrypting.
\li The \c contentTypeMain returned typically starts with
"multipart/" while providing a "protocol" and a "micalg" parameter: just
add an appropriate \c "; boundary=[your \c boundary \c string]" to get
the complete Content-Type value to be used for the MIME object embedding
both the signed part and the signature part (or - in case of
encrypting - the version part and the code part, resp.).
\li If \c contentTypeVersion is holding a non-zero-length string an
additional MIME part must added immediately before the code part, this
version part's MIME headers must have the unaltered values of
\c contentTypeVersion and (if they are holding non-zero-length strings)
\c contentDispVersion and \c contentTEncVersion, the unaltered contents
of \c bodyTextVersion must be it's body.
\li The value returned in \c contentTypeCode is specifying the complete
Content-Type to be used for this multipart MIME object's signature part
(or - in case of encrypting - for the code part following after the
version part, resp.), you should not add/change/remove anything here
but just use it's unaltered value for specifying the Content-Type header
of the respective MIME part.
\li The same applies to the \c contentDispCode value: just use it's
unaltered value to specify the Content-Disposition header entry of
the respective MIME part.
\li The same applies to the \c contentTEncCode value: just use it's
unaltered value to specify the Content-Transfer-Encoding header of
the respective MIME part.
<b>If</b> value returned in \c makeMimeObject is <b>FALSE</b> the
text strings returned in \c flatTextPrefix and \c flatTextPostfix
should be used to build a frame around the cleartext and the code
bloc holding the signature (or - in case of encrypting - the encoded
data bloc, resp.).<br>
If \c includeCleartext is TRUE this frame should also include the
cleartext as first bloc, this bloc should be divided from the code bloc
by the contents of \c flatTextSeparator - typically this is used for
signing but not when encrypting.<br>
If \c includeCleartext is FALSE you should ignore both the cleartext
and the \c flatTextSeparator parameter.
<b>How to use StructuringInfo data in your program:</b>
\li To compose a signed message please act as described below.
\li For constructing an encrypted message just replace the
\c signMessage() call by the respective \c encryptMessage() call
and then proceed exactly the same way.
\li In any case make <b>sure</b> to free your \c ciphertext <b>and</b>
to call \c free_StructuringInfo() when you are done with processing
the data returned by the signing (or encrypting, resp.) function.
\verbatim
char* ciphertext;
StructuringInfo structInf;
if( ! signMessage( cleartext, &ciphertext, certificate,
&structuring ) ) {
myErrorDialog( "Error: could not sign the message!" );
} else {
if( structInf.makeMimeObject ) {
// Build the main MIME object.
// This is done by
// using the header values returned in
// structInf.contentTypeMain and in
// structInf.contentDispMain and in
// structInf.contentTEncMain.
..
if( ! structInf.makeMultiMime ) {
// Build the main MIME object's body.
// This is done by
// using the code bloc returned in
// ciphertext.
..
} else {
// Build the encapsulated MIME parts.
if( structInf.includeCleartext ) {
// Build a MIME part holding the cleartext.
// This is done by
// using the original cleartext's headers and by
// taking it's original body text.
..
}
if( structInf.contentTypeVersion
&& 0 < strlen( structInf.contentTypeVersion ) ) {
// Build a MIME part holding the version information.
// This is done by
// using the header values returned in
// structInf.contentTypeVersion and
// structInf.contentDispVersion and
// structInf.contentTEncVersion and by
// taking the body contents returned in
// structInf.bodyTextVersion.
..
}
if( structInf.contentTypeCode
&& 0 < strlen( structInf.contentTypeCode ) ) {
// Build a MIME part holding the code information.
// This is done by
// using the header values returned in
// structInf.contentTypeCode and
// structInf.contentDispCode and
// structInf.contentTEncCode and by
// taking the body contents returned in
// ciphertext.
..
} else {
// Plugin error!
myErrorDialog( "Error: Cryptography plugin returned a main"
"Content-Type=Multipart/.. but did not "
"specify the code bloc's Content-Type header."
"\nYou may report this bug:"
"\n" + cryptplug.bugURL() );
}
}
} else {
// Build a plain message body
// based on the values returned in structInf.
// Note: We do _not_ insert line breaks between the parts since
// it is the plugin job to provide us with ready-to-use
// texts containing all neccessary line breaks.
strcpy( myMessageBody, structInf.plainTextPrefix );
if( structInf.includeCleartext ) {
strcat( myMessageBody, cleartext );
strcat( myMessageBody, structInf.plainTextSeparator );
}
strcat( myMessageBody, *ciphertext );
strcat( myMessageBody, structInf.plainTextPostfix );
}
// free the memory that was allocated
// for the ciphertext
free( ciphertext );
// free the memory that was allocated
// for our StructuringInfo's char* members
free_StructuringInfo( &structuring );
}
\endverbatim
\note Make sure to call \c free_StructuringInfo() when you are done
with processing the StructuringInfo data!
\see free_StructuringInfo
\see signMessage, encryptMessage, encryptAndSignMessage
*/
struct StructuringInfo {
bool includeCleartext; /*!< specifies whether we should include the
cleartext as first part of our multipart
MIME object (or - for non-MIME
messages - as flat text to be set before
the ciphertext, resp.), typically this
is TRUE when signing mails but FALSE
when encrypting<br>
(this parameter is relevant no matter
whether \c makeMimeObject is TRUE or
FALSE) */
bool makeMimeObject; /*!< specifies whether we should create a MIME
object or a flat text message body */
/* the following are used for MIME messages only */
bool makeMultiMime; /*!< specifies whether we should create a
'Multipart' MIME object or a single part
object, if FALSE only \c contentTypeMain,
\c contentDispMain and \c contentTEncMain
may be used and all other parameters have
to be ignored<br>
(ignore this parameter if \c makeMimeObject
is FALSE) */
char* contentTypeMain; /*!< value of the main 'Content-Type'
header<br>
(ignore this parameter if \c makeMimeObject
is FALSE) */
char* contentDispMain; /*!< value of the main 'Content-Disposition'
header<br>
(ignore this parameter if \c makeMimeObject
is FALSE) */
char* contentTEncMain; /*!< value of the main
'Content-TransferEncoding' header<br>
(ignore this parameter if \c makeMimeObject
is FALSE) */
char* contentTypeVersion; /*!< 'Content-Type' of the additional version
part that might preceed the code part -
if NULL or zero length no version part
must be created<br>
(ignore this parameter if either
\c makeMimeObject or \c makeMultiMime
is FALSE) */
char* contentDispVersion; /*!< 'Content-Disposition' of the additional
preceeding the code part (only valid if
\c contentTypeVersion holds a
non-zero-length string)<br>
(ignore this parameter if either
\c makeMimeObject or \c makeMultiMime
is FALSE or if \c contentTypeVersion does
not return a non-zero-length string) */
char* contentTEncVersion; /*!< 'Content-Transfer-Encoding' of the
additional version part (only valid if
\c contentTypeVersion holds a
non-zero-length string)<br>
(ignore this parameter if either
\c makeMimeObject or \c makeMultiMime
is FALSE or if \c contentTypeVersion does
not return a non-zero-length string) */
char* bodyTextVersion; /*!< body text of the additional version part
(only valid if \c contentTypeVersion
holds a non-zero-length string)<br>
(ignore this parameter if either
\c makeMimeObject or \c makeMultiMime
is FALSE or if \c contentTypeVersion does
not return a non-zero-length string) */
char* contentTypeCode; /*!< 'Content-Type' of the code part holding
the signature code (or the encrypted
data, resp.)<br>
(ignore this parameter if either
\c makeMimeObject or \c makeMultiMime
is FALSE) */
char* contentDispCode; /*!< 'Content-Disposition' of the code part<br>
(ignore this parameter if either
\c makeMimeObject or \c makeMultiMime
is FALSE or if \c contentTypeCode does
not return a non-zero-length string) */
char* contentTEncCode; /*!< 'Content-Type' of the code part<br>
(ignore this parameter if either
\c makeMimeObject or \c makeMultiMime
is FALSE or if \c contentTypeCode does
not return a non-zero-length string) */
/* the following are used for flat non-MIME messages only */
char* flatTextPrefix; /*!< text to preceed the main text (or the
code bloc containing the encrypted main
text, resp.)<br>
(ignore this parameter if
\c makeMimeObject is TRUE) */
char* flatTextSeparator; /*!< text to be put between the main text and
the signature code bloc (not used when
encrypting)<br>
(ignore this parameter if
\c makeMimeObject is TRUE or if
\c includeCleartext is FALSE) */
char* flatTextPostfix; /*!< text to follow the signature code bloc
(or the encrypted data bloc, resp.)<br>
(ignore this parameter if
\c makeMimeObject is TRUE) */
};
/*! \ingroup groupAdUsoInterno
\brief If you are not planning to write your own cryptography
plugin <b>you should ignore this</b> function!
Usage of this function is depreciated for plugin users but highly
recommended for plugin implementors since this is an internal
function for initializing all char* members of a \c StructuringInfo
struct.<br>
This function <b>must</b> be called in <b>any</b> plugin's
implementations of the following functions:
\c signMessage() <br>
\c encryptMessage() <br>
\c encryptAndSignMessage()
Calling this function makes sure the corresponding
\c free_StructuringInfo() calls which will be embedded by
your plugin's users into their code will be able to
determine which of the char* members belonging to the
respective's StructuringInfo had been allocated memory
for during previous signing or encrypting actions.
\see free_StructuringInfo, StructuringInfo
\see signMessage, encryptMessage, encryptAndSignMessage
*/
inline void init_StructuringInfo( struct StructuringInfo* s )
{
if( ! s ) return;
s->includeCleartext = false;
s->makeMimeObject = false;
s->makeMultiMime = false;
s->contentTypeMain = 0;
s->contentDispMain = 0;
s->contentTEncMain = 0;
s->contentTypeVersion = 0;
s->contentDispVersion = 0;
s->contentTEncVersion = 0;
s->bodyTextVersion = 0;
s->contentTypeCode = 0;
s->contentDispCode = 0;
s->contentTEncCode = 0;
s->flatTextPrefix = 0;
s->flatTextSeparator = 0;
s->flatTextPostfix = 0;
}
/*! \ingroup groupSignCryptAct
\brief Important method for freeing all memory that was allocated
for the char* members of a \c StructuringInfo struct - use
this function after <b>each</b> signing or encrypting function
call.
\note Even when intending to call \c encryptMessage() immediately
after having called \c signMessage() you first <b>must</b> call
the \c free_StructuringInfo() function to make sure all memory is
set free that was allocated for your StructuringInfo's char* members
by the \c signMessage() function!
\see StructuringInfo
*/
inline void free_StructuringInfo( struct StructuringInfo* s )
{
if( ! s ) return;
if( s->contentTypeMain ) free( s->contentTypeMain );
if( s->contentDispMain ) free( s->contentDispMain );
if( s->contentTEncMain ) free( s->contentTEncMain );
if( s->contentTypeVersion ) free( s->contentTypeVersion );
if( s->contentDispVersion ) free( s->contentDispVersion );
if( s->contentTEncVersion ) free( s->contentTEncVersion );
if( s->bodyTextVersion ) free( s->bodyTextVersion );
if( s->contentTypeCode ) free( s->contentTypeCode );
if( s->contentDispCode ) free( s->contentDispCode );
if( s->contentTEncCode ) free( s->contentTEncCode );
if( s->flatTextPrefix ) free( s->flatTextPrefix );
if( s->flatTextSeparator ) free( s->flatTextSeparator );
if( s->flatTextPostfix ) free( s->flatTextPostfix );
}
/*! \ingroup groupSignAct
*/
struct SignatureMetaDataExtendedInfo
{
struct tm* creation_time;
SigStatusFlags sigStatusFlags;
char* status_text;
char* keyid;
char* fingerprint;
char* algo;
char* userid;
char* name;
char* comment;
char** emailList;
int emailCount;
unsigned long algo_num;
unsigned long validity;
unsigned long userid_num;
unsigned long keylen;
unsigned long key_created;
unsigned long key_expires;
};
/*! \ingroup groupSignAct
*/
struct SignatureMetaData {
char* status;
struct SignatureMetaDataExtendedInfo* extended_info;
int extended_info_count;
int status_code;
};
/*! \ingroup groupSignAct
\brief Checks whether the signature of a message is
valid.
\c cleartext must never be 0 but be a valid pointer.
If \c *cleartext > 0 then **cleartext specifies the message text
that was signed and \c signaturetext is the signature itself.
If \c *cleartext == 0 is an empty string then \c signaturetext is
supposed to contain an opaque signed message part. After checking the
data and verifying the signature the cleartext of the message will be
returned in \c cleartext. The user must free the respective memory
ocupied by *cleartext.
Depending on the configuration, MUAs might not need to use this.
If \c sigmeta is non-null, the
\c SignatureMetaData object pointed to will
contain meta information about the signature after the
function call.
*/
bool checkMessageSignature( char** cleartext,
const char* signaturetext,
bool signatureIsBinary,
int signatureLen,
struct SignatureMetaData* sigmeta,
char** attrOrder,
const char* unknownAttrsHandling );
/*! \ingroup groupCryptAct
\brief Tries to decrypt an email message
\c ciphertext and returns the decrypted
message in \c cleartext.
The \c certificate is used for decryption. If
the message could be decrypted, the function returns
\c true, otherwise
\c false.
*/
bool decryptMessage( const char* ciphertext,
bool cipherIsBinary,
int cipherLen,
const char** cleartext,
const char* certificate,
int* errId,
char** errTxt );
/*! \ingroup groupCryptAct
\brief Combines the functionality of
\c checkMessageSignature() and
\c decryptMessage().
If \c certificate is \c NULL,
the default certificate will be used.
If \c sigmeta is non-null, the \c SignatureMetaData
object pointed to will contain meta information about
the signature after the function call.
*/
bool decryptAndCheckMessage( const char* ciphertext,
bool cipherIsBinary,
int cipherLen,
const char** cleartext,
const char* certificate,
bool* signatureFound,
struct SignatureMetaData* sigmeta,
int* errId,
char** errTxt,
char** attrOrder,
const char* unknownAttrsHandling );
struct DnPair {
char *key;
char *value;
};
struct CertificateInfo {
char** userid;
char* userid_0_org;
char* serial;
char* fingerprint;
char* issuer_org;
char* issuer_reord;
char* chainid;
char* caps;
unsigned long created;
unsigned long expire;
int secret : 1;
int invalid : 1;
int expired : 1;
int disabled : 1;
struct DnPair *dnarray; /* parsed values from userid[0] */
};
/*!
Import a certificate from memory.
*/
GpgME::ImportResult importCertificateFromMem( const char* data, size_t length );
}; // class CryptPlug
class SMIMECryptPlug : public CryptPlug {
public:
SMIMECryptPlug();
};
class OpenPGPCryptPlug : public CryptPlug {
public:
OpenPGPCryptPlug();
};
#endif /*CRYPTPLUG_H*/