provider-decoder - The OSSL_DECODER library <-> provider functions
#include <openssl/core_dispatch.h>
/*
* None of these are actual functions, but are displayed like this for
* the function signatures for functions that are offered as function
* pointers in OSSL_DISPATCH arrays.
*/
/* Decoder parameter accessor and descriptor */
const OSSL_PARAM *OSSL_FUNC_decoder_gettable_params(void *provctx);
int OSSL_FUNC_decoder_get_params(OSSL_PARAM params[]);
/* Functions to construct / destruct / manipulate the decoder context */
void *OSSL_FUNC_decoder_newctx(void *provctx);
void OSSL_FUNC_decoder_freectx(void *ctx);
const OSSL_PARAM *OSSL_FUNC_decoder_settable_ctx_params(void *provctx);
int OSSL_FUNC_decoder_set_ctx_params(void *ctx, const OSSL_PARAM params[]);
/* Functions to check selection support */
int OSSL_FUNC_decoder_does_selection(void *provctx, int selection);
/* Functions to decode object data */
int OSSL_FUNC_decoder_decode(void *ctx, OSSL_CORE_BIO *in,
int selection,
OSSL_CALLBACK *data_cb, void *data_cbarg,
OSSL_PASSPHRASE_CALLBACK *cb, void *cbarg);
/* Functions to export a decoded object */
int OSSL_FUNC_decoder_export_object(void *ctx,
const void *objref, size_t objref_sz,
OSSL_CALLBACK *export_cb,
void *export_cbarg);
The term "decode" is used throughout this manual. This includes but
is not limited to deserialization as individual decoders can also
do decoding into intermediate data formats.
The DECODER operation is a generic method to create a provider-native object
reference or intermediate decoded data from an encoded form read from the
given
OSSL_CORE_BIO. If the caller wants to decode data from memory, it
should provide a
BIO_s_mem(3) BIO. The decoded data or object
reference is passed along with eventual metadata to the
metadata_cb as
OSSL_PARAM(3) parameters.
The decoder doesn't need to know more about the
OSSL_CORE_BIO pointer
than being able to pass it to the appropriate BIO upcalls (see "Core
functions" in
provider-base(7)).
The DECODER implementation may be part of a chain, where data is passed from one
to the next. For example, there may be an implementation to decode an object
from PEM to DER, and another one that decodes DER to a provider-native object.
The last decoding step in the decoding chain is usually supposed to create a
provider-native object referenced by an object reference. To import that
object into a different provider the
OSSL_FUNC_decoder_export_object()
can be called as the final step of the decoding process.
All "functions" mentioned here are passed as function pointers between
libcrypto and the provider in
OSSL_DISPATCH(3) arrays via
OSSL_ALGORITHM(3) arrays that are returned by the provider's
provider_query_operation() function (see "Provider Functions"
in
provider-base(7)).
All these "functions" have a corresponding function type definition
named
OSSL_FUNC_{name}_fn, and a helper function to retrieve the
function pointer from an
OSSL_DISPATCH(3) element named
OSSL_FUNC_{name}. For example, the "function"
OSSL_FUNC_decoder_decode() has these:
typedef int
(OSSL_FUNC_decoder_decode_fn)(void *ctx, OSSL_CORE_BIO *in,
int selection,
OSSL_CALLBACK *data_cb, void *data_cbarg,
OSSL_PASSPHRASE_CALLBACK *cb, void *cbarg);
static ossl_inline OSSL_FUNC_decoder_decode_fn*
OSSL_FUNC_decoder_decode(const OSSL_DISPATCH *opf);
OSSL_DISPATCH(3) arrays are indexed by numbers that are provided as
macros in
openssl-core_dispatch.h(7), as follows:
OSSL_FUNC_decoder_get_params OSSL_FUNC_DECODER_GET_PARAMS
OSSL_FUNC_decoder_gettable_params OSSL_FUNC_DECODER_GETTABLE_PARAMS
OSSL_FUNC_decoder_newctx OSSL_FUNC_DECODER_NEWCTX
OSSL_FUNC_decoder_freectx OSSL_FUNC_DECODER_FREECTX
OSSL_FUNC_decoder_set_ctx_params OSSL_FUNC_DECODER_SET_CTX_PARAMS
OSSL_FUNC_decoder_settable_ctx_params OSSL_FUNC_DECODER_SETTABLE_CTX_PARAMS
OSSL_FUNC_decoder_does_selection OSSL_FUNC_DECODER_DOES_SELECTION
OSSL_FUNC_decoder_decode OSSL_FUNC_DECODER_DECODE
OSSL_FUNC_decoder_export_object OSSL_FUNC_DECODER_EXPORT_OBJECT
The name of an implementation should match the target type of object it decodes.
For example, an implementation that decodes an RSA key should be named
"RSA". Likewise, an implementation that decodes DER data from PEM
input should be named "DER".
Properties can be used to further specify details about an implementation:
- input
- This property is used to specify what format of input the
implementation can decode.
This property is mandatory.
OpenSSL providers recognize the following input types:
- pem
- An implementation with that input type decodes PEM
formatted data.
- der
- An implementation with that input type decodes DER
formatted data.
- msblob
- An implementation with that input type decodes MSBLOB
formatted data.
- pvk
- An implementation with that input type decodes PVK
formatted data.
- structure
- This property is used to specify the structure that the
decoded data is expected to have.
This property is optional.
Structures currently recognised by built-in decoders:
- "type-specific"
- Type specific structure.
- "pkcs8"
- Structure according to the PKCS#8 specification.
- "SubjectPublicKeyInfo"
- Encoding of public keys according to the Subject Public Key
Info of RFC 5280.
The possible values of both these properties is open ended. A provider may very
well specify input types and structures that libcrypto doesn't know anything
about.
Sometimes, an object has more than one subset of data that is interesting to
treat separately or together. It's possible to specify what subsets are to be
decoded, with a set of bits
selection that are passed in an
int.
This set of bits depend entirely on what kind of provider-side object is to be
decoded. For example, those bits are assumed to be the same as those used with
provider-keymgmt(7) (see "Key Objects" in
provider-keymgmt(7)) when the object is an asymmetric keypair - e.g.,
OSSL_KEYMGMT_SELECT_PRIVATE_KEY if the object to be decoded is supposed
to contain private key components.
OSSL_FUNC_decoder_does_selection() should tell if a particular
implementation supports any of the combinations given by
selection.
OSSL_FUNC_decoder_newctx() returns a context to be used with the rest of
the functions.
OSSL_FUNC_decoder_freectx() frees the given
ctx as created by
OSSL_FUNC_decoder_newctx().
OSSL_FUNC_decoder_set_ctx_params() sets context data according to
parameters from
params that it recognises. Unrecognised parameters
should be ignored. Passing NULL for
params should return true.
OSSL_FUNC_decoder_settable_ctx_params() returns a constant
OSSL_PARAM(3) array describing the parameters that
OSSL_FUNC_decoder_set_ctx_params() can handle.
See
OSSL_PARAM(3) for further details on the parameters structure used by
OSSL_FUNC_decoder_set_ctx_params() and
OSSL_FUNC_decoder_settable_ctx_params().
When a provider-native object is created by a decoder it would be unsuitable for
direct use with a foreign provider. The export function allows for exporting
the object into that foreign provider if the foreign provider supports the
type of the object and provides an import function.
OSSL_FUNC_decoder_export_object() should export the object of size
objref_sz referenced by
objref as an
OSSL_PARAM(3) array
and pass that into the
export_cb as well as the given
export_cbarg.
OSSL_FUNC_decoder_decode() should decode the data as read from the
OSSL_CORE_BIO in to produce decoded data or an object to be
passed as reference in an
OSSL_PARAM(3) array along with possible other
metadata that was decoded from the input. This
OSSL_PARAM(3) array is
then passed to the
data_cb callback. The
selection bits, if
relevant, should determine what the input data should contain. The decoding
functions also take an
OSSL_PASSPHRASE_CALLBACK(3) function pointer
along with a pointer to application data
cbarg, which should be used
when a pass phrase prompt is needed.
It's important to understand that the return value from this function is
interpreted as follows:
- True (1)
- This means "carry on the decoding process", and
is meaningful even though this function couldn't decode the input into
anything, because there may be another decoder implementation that can
decode it into something.
The data_cb callback should never be called when this function can't
decode the input into anything.
- False (0)
- This means "stop the decoding process", and is
meaningful when the input could be decoded into some sort of object that
this function understands, but further treatment of that object results
into errors that won't be possible for some other decoder implementation
to get a different result.
The conditions to stop the decoding process are at the discretion of the
implementation.
There are currently no operation parameters currently recognised by the built-in
decoders.
Parameters currently recognised by the built-in pass phrase callback:
- "info" (OSSL_PASSPHRASE_PARAM_INFO)
<UTF8 string>
- A string of information that will become part of the pass
phrase prompt. This could be used to give the user information on what
kind of object it's being prompted for.
OSSL_FUNC_decoder_newctx() returns a pointer to a context, or NULL on
failure.
OSSL_FUNC_decoder_set_ctx_params() returns 1, unless a recognised
parameter was invalid or caused an error, for which 0 is returned.
OSSL_FUNC_decoder_settable_ctx_params() returns a pointer to an array of
constant
OSSL_PARAM(3) elements.
OSSL_FUNC_decoder_does_selection() returns 1 if the decoder
implementation supports any of the
selection bits, otherwise 0.
OSSL_FUNC_decoder_decode() returns 1 to signal that the decoding process
should continue, or 0 to signal that it should stop.
provider(7)
The DECODER interface was introduced in OpenSSL 3.0.
Copyright 2019-2023 The OpenSSL Project Authors. All Rights Reserved.
Licensed under the Apache License 2.0 (the "License"). You may not use
this file except in compliance with the License. You can obtain a copy in the
file LICENSE in the source distribution or at
<
https://www.openssl.org/source/license.html>.