52a1be4351
support for AES and OpenBSD's hardware crypto.
188 lines
7.5 KiB
Groff
188 lines
7.5 KiB
Groff
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OpenSSL ASN1 Revision
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=====================
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This document describes some of the issues relating to the new ASN1 code.
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Previous OpenSSL ASN1 problems
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=============================
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OK why did the OpenSSL ASN1 code need revising in the first place? Well
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there are lots of reasons some of which are included below...
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1. The code is difficult to read and write. For every single ASN1 structure
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(e.g. SEQUENCE) four functions need to be written for new, free, encode and
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decode operations. This is a very painful and error prone operation. Very few
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people have ever written any OpenSSL ASN1 and those that have usually wish
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they hadn't.
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2. Partly because of 1. the code is bloated and takes up a disproportionate
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amount of space. The SEQUENCE encoder is particularly bad: it essentially
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contains two copies of the same operation, one to compute the SEQUENCE length
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and the other to encode it.
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3. The code is memory based: that is it expects to be able to read the whole
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structure from memory. This is fine for small structures but if you have a
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(say) 1Gb PKCS#7 signedData structure it isn't such a good idea...
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4. The code for the ASN1 IMPLICIT tag is evil. It is handled by temporarily
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changing the tag to the expected one, attempting to read it, then changing it
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back again. This means that decode buffers have to be writable even though they
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are ultimately unchanged. This gets in the way of constification.
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5. The handling of EXPLICIT isn't much better. It adds a chunk of code into
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the decoder and encoder for every EXPLICIT tag.
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6. APPLICATION and PRIVATE tags aren't even supported at all.
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7. Even IMPLICIT isn't complete: there is no support for implicitly tagged
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types that are not OPTIONAL.
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8. Much of the code assumes that a tag will fit in a single octet. This is
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only true if the tag is 30 or less (mercifully tags over 30 are rare).
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9. The ASN1 CHOICE type has to be largely handled manually, there aren't any
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macros that properly support it.
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10. Encoders have no concept of OPTIONAL and have no error checking. If the
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passed structure contains a NULL in a mandatory field it will not be encoded,
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resulting in an invalid structure.
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11. It is tricky to add ASN1 encoders and decoders to external applications.
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Template model
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==============
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One of the major problems with revision is the sheer volume of the ASN1 code.
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Attempts to change (for example) the IMPLICIT behaviour would result in a
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modification of *every* single decode function.
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I decided to adopt a template based approach. I'm using the term 'template'
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in a manner similar to SNACC templates: it has nothing to do with C++
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templates.
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A template is a description of an ASN1 module as several constant C structures.
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It describes in a machine readable way exactly how the ASN1 structure should
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behave. If this template contains enough detail then it is possible to write
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versions of new, free, encode, decode (and possibly others operations) that
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operate on templates.
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Instead of having to write code to handle each operation only a single
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template needs to be written. If new operations are needed (such as a 'print'
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operation) only a single new template based function needs to be written
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which will then automatically handle all existing templates.
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Plans for revision
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==================
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The revision will consist of the following steps. Other than the first two
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these can be handled in any order.
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o Design and write template new, free, encode and decode operations, initially
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memory based. *DONE*
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o Convert existing ASN1 code to template form. *IN PROGRESS*
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o Convert an existing ASN1 compiler (probably SNACC) to output templates
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in OpenSSL form.
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o Add support for BIO based ASN1 encoders and decoders to handle large
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structures, initially blocking I/O.
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o Add support for non blocking I/O: this is quite a bit harder than blocking
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I/O.
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o Add new ASN1 structures, such as OCSP, CRMF, S/MIME v3 (CMS), attribute
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certificates etc etc.
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Description of major changes
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============================
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The BOOLEAN type now takes three values. 0xff is TRUE, 0 is FALSE and -1 is
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absent. The meaning of absent depends on the context. If for example the
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boolean type is DEFAULT FALSE (as in the case of the critical flag for
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certificate extensions) then -1 is FALSE, if DEFAULT TRUE then -1 is TRUE.
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Usually the value will only ever be read via an API which will hide this from
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an application.
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There is an evil bug in the old ASN1 code that mishandles OPTIONAL with
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SEQUENCE OF or SET OF. These are both implemented as a STACK structure. The
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old code would omit the structure if the STACK was NULL (which is fine) or if
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it had zero elements (which is NOT OK). This causes problems because an empty
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SEQUENCE OF or SET OF will result in an empty STACK when it is decoded but when
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it is encoded it will be omitted resulting in different encodings. The new code
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only omits the encoding if the STACK is NULL, if it contains zero elements it
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is encoded and empty. There is an additional problem though: because an empty
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STACK was omitted, sometimes the corresponding *_new() function would
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initialize the STACK to empty so an application could immediately use it, if
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this is done with the new code (i.e. a NULL) it wont work. Therefore a new
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STACK should be allocated first. One instance of this is the X509_CRL list of
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revoked certificates: a helper function X509_CRL_add0_revoked() has been added
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for this purpose.
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The X509_ATTRIBUTE structure used to have an element called 'set' which took
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the value 1 if the attribute value was a SET OF or 0 if it was a single. Due
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to the behaviour of CHOICE in the new code this has been changed to a field
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called 'single' which is 0 for a SET OF and 1 for single. The old field has
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been deleted to deliberately break source compatibility. Since this structure
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is normally accessed via higher level functions this shouldn't break too much.
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The X509_REQ_INFO certificate request info structure no longer has a field
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called 'req_kludge'. This used to be set to 1 if the attributes field was
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(incorrectly) omitted. You can check to see if the field is omitted now by
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checking if the attributes field is NULL. Similarly if you need to omit
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the field then free attributes and set it to NULL.
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The top level 'detached' field in the PKCS7 structure is no longer set when
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a PKCS#7 structure is read in. PKCS7_is_detached() should be called instead.
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The behaviour of PKCS7_get_detached() is unaffected.
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The values of 'type' in the GENERAL_NAME structure have changed. This is
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because the old code use the ASN1 initial octet as the selector. The new
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code uses the index in the ASN1_CHOICE template.
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The DIST_POINT_NAME structure has changed to be a true CHOICE type.
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typedef struct DIST_POINT_NAME_st {
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int type;
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union {
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STACK_OF(GENERAL_NAME) *fullname;
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STACK_OF(X509_NAME_ENTRY) *relativename;
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} name;
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} DIST_POINT_NAME;
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This means that name.fullname or name.relativename should be set
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and type reflects the option. That is if name.fullname is set then
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type is 0 and if name.relativename is set type is 1.
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With the old code using the i2d functions would typically involve:
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unsigned char *buf, *p;
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int len;
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/* Find length of encoding */
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len = i2d_SOMETHING(x, NULL);
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/* Allocate buffer */
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buf = OPENSSL_malloc(len);
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if(buf == NULL) {
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/* Malloc error */
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}
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/* Use temp variable because &p gets updated to point to end of
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* encoding.
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*/
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p = buf;
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i2d_SOMETHING(x, &p);
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Using the new i2d you can also do:
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unsigned char *buf = NULL;
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int len;
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len = i2d_SOMETHING(x, &buf);
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if(len < 0) {
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/* Malloc error */
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}
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and it will automatically allocate and populate a buffer with the
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encoding. After this call 'buf' will point to the start of the
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encoding which is len bytes long.
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