/* asn1t.h */ /* Written by Dr Stephen N Henson (steve@openssl.org) for the OpenSSL * project 2000. */ /* ==================================================================== * Copyright (c) 2000-2005 The OpenSSL Project. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * * 3. All advertising materials mentioning features or use of this * software must display the following acknowledgment: * "This product includes software developed by the OpenSSL Project * for use in the OpenSSL Toolkit. (http://www.OpenSSL.org/)" * * 4. The names "OpenSSL Toolkit" and "OpenSSL Project" must not be used to * endorse or promote products derived from this software without * prior written permission. For written permission, please contact * licensing@OpenSSL.org. * * 5. Products derived from this software may not be called "OpenSSL" * nor may "OpenSSL" appear in their names without prior written * permission of the OpenSSL Project. * * 6. Redistributions of any form whatsoever must retain the following * acknowledgment: * "This product includes software developed by the OpenSSL Project * for use in the OpenSSL Toolkit (http://www.OpenSSL.org/)" * * THIS SOFTWARE IS PROVIDED BY THE OpenSSL PROJECT ``AS IS'' AND ANY * EXPRESSED OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE OpenSSL PROJECT OR * ITS CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED * OF THE POSSIBILITY OF SUCH DAMAGE. * ==================================================================== * * This product includes cryptographic software written by Eric Young * (eay@cryptsoft.com). This product includes software written by Tim * Hudson (tjh@cryptsoft.com). * */ module deimos.openssl.asn1t; import deimos.openssl._d_util; import deimos.openssl.ossl_typ; // Needed for ASN1_BOOLEAN, etc. import core.stdc.config; public import deimos.openssl.e_os2; public import deimos.openssl.asn1; /* ASN1 template defines, structures and functions */ extern (C): nothrow: /+ FIXME: Not yet ported. #ifndef OPENSSL_EXPORT_VAR_AS_FUNCTION /* Macro to obtain ASN1_ADB pointer from a type (only used internally) */ #define ASN1_ADB_ptr(iptr) ((const(ASN1_ADB)*)(iptr)) /* Macros for start and end of ASN1_ITEM definition */ #define ASN1_ITEM_start(itname) \ OPENSSL_GLOBAL const ASN1_ITEM itname##_it = { #define ASN1_ITEM_end(itname) \ }; #else /* Macro to obtain ASN1_ADB pointer from a type (only used internally) */ #define ASN1_ADB_ptr(iptr) ((const(ASN1_ADB)*)(iptr())) /* Macros for start and end of ASN1_ITEM definition */ #define ASN1_ITEM_start(itname) \ const(ASN1_ITEM)* itname##_it() \ { \ static const ASN1_ITEM local_it = { #define ASN1_ITEM_end(itname) \ }; \ return &local_it; \ } #endif /* Macros to aid ASN1 template writing */ #define ASN1_ITEM_TEMPLATE(tname) \ static const ASN1_TEMPLATE tname##_item_tt #define ASN1_ITEM_TEMPLATE_END(tname) \ ;\ ASN1_ITEM_start(tname) \ ASN1_ITYPE_PRIMITIVE,\ -1,\ &tname##_item_tt,\ 0,\ NULL,\ 0,\ #tname \ ASN1_ITEM_end(tname) /* This is a ASN1 type which just embeds a template */ /* This pair helps declare a SEQUENCE. We can do: * * ASN1_SEQUENCE(stname) = { * ... SEQUENCE components ... * } ASN1_SEQUENCE_END(stname) * * This will produce an ASN1_ITEM called stname_it * for a structure called stname. * * If you want the same structure but a different * name then use: * * ASN1_SEQUENCE(itname) = { * ... SEQUENCE components ... * } ASN1_SEQUENCE_END_name(stname, itname) * * This will create an item called itname_it using * a structure called stname. */ #define ASN1_SEQUENCE(tname) \ static const ASN1_TEMPLATE[] tname##_seq_tt #define ASN1_SEQUENCE_END(stname) ASN1_SEQUENCE_END_name(stname, stname) #define ASN1_SEQUENCE_END_name(stname, tname) \ ;\ ASN1_ITEM_start(tname) \ ASN1_ITYPE_SEQUENCE,\ V_ASN1_SEQUENCE,\ tname##_seq_tt,\ sizeof(tname##_seq_tt) / sizeof(ASN1_TEMPLATE),\ NULL,\ sizeof(stname),\ #stname \ ASN1_ITEM_end(tname) #define ASN1_NDEF_SEQUENCE(tname) \ ASN1_SEQUENCE(tname) #define ASN1_NDEF_SEQUENCE_cb(tname, cb) \ ASN1_SEQUENCE_cb(tname, cb) #define ASN1_SEQUENCE_cb(tname, cb) \ static const ASN1_AUX tname##_aux = {NULL, 0, 0, 0, cb, 0}; \ ASN1_SEQUENCE(tname) #define ASN1_BROKEN_SEQUENCE(tname) \ static const ASN1_AUX tname##_aux = {NULL, ASN1_AFLG_BROKEN, 0, 0, 0, 0}; \ ASN1_SEQUENCE(tname) #define ASN1_SEQUENCE_ref(tname, cb, lck) \ static const ASN1_AUX tname##_aux = {NULL, ASN1_AFLG_REFCOUNT, offsetof(tname, references), lck, cb, 0}; \ ASN1_SEQUENCE(tname) #define ASN1_SEQUENCE_enc(tname, enc, cb) \ static const ASN1_AUX tname##_aux = {NULL, ASN1_AFLG_ENCODING, 0, 0, cb, offsetof(tname, enc)}; \ ASN1_SEQUENCE(tname) #define ASN1_NDEF_SEQUENCE_END(tname) \ ;\ ASN1_ITEM_start(tname) \ ASN1_ITYPE_NDEF_SEQUENCE,\ V_ASN1_SEQUENCE,\ tname##_seq_tt,\ sizeof(tname##_seq_tt) / sizeof(ASN1_TEMPLATE),\ NULL,\ sizeof(tname),\ #tname \ ASN1_ITEM_end(tname) #define ASN1_BROKEN_SEQUENCE_END(stname) ASN1_SEQUENCE_END_ref(stname, stname) #define ASN1_SEQUENCE_END_enc(stname, tname) ASN1_SEQUENCE_END_ref(stname, tname) #define ASN1_SEQUENCE_END_cb(stname, tname) ASN1_SEQUENCE_END_ref(stname, tname) #define ASN1_SEQUENCE_END_ref(stname, tname) \ ;\ ASN1_ITEM_start(tname) \ ASN1_ITYPE_SEQUENCE,\ V_ASN1_SEQUENCE,\ tname##_seq_tt,\ sizeof(tname##_seq_tt) / sizeof(ASN1_TEMPLATE),\ &tname##_aux,\ sizeof(stname),\ #stname \ ASN1_ITEM_end(tname) #define ASN1_NDEF_SEQUENCE_END_cb(stname, tname) \ ;\ ASN1_ITEM_start(tname) \ ASN1_ITYPE_NDEF_SEQUENCE,\ V_ASN1_SEQUENCE,\ tname##_seq_tt,\ sizeof(tname##_seq_tt) / sizeof(ASN1_TEMPLATE),\ &tname##_aux,\ sizeof(stname),\ #stname \ ASN1_ITEM_end(tname) /* This pair helps declare a CHOICE type. We can do: * * ASN1_CHOICE(chname) = { * ... CHOICE options ... * ASN1_CHOICE_END(chname) * * This will produce an ASN1_ITEM called chname_it * for a structure called chname. The structure * definition must look like this: * typedef struct { * int type; * union { * ASN1_SOMETHING* opt1; * ASN1_SOMEOTHER* opt2; * } value; * } chname; * * the name of the selector must be 'type'. * to use an alternative selector name use the * ASN1_CHOICE_END_selector() version. */ #define ASN1_CHOICE(tname) \ static const ASN1_TEMPLATE[] tname##_ch_tt #define ASN1_CHOICE_cb(tname, cb) \ static const ASN1_AUX tname##_aux = {NULL, 0, 0, 0, cb, 0}; \ ASN1_CHOICE(tname) #define ASN1_CHOICE_END(stname) ASN1_CHOICE_END_name(stname, stname) #define ASN1_CHOICE_END_name(stname, tname) ASN1_CHOICE_END_selector(stname, tname, type) #define ASN1_CHOICE_END_selector(stname, tname, selname) \ ;\ ASN1_ITEM_start(tname) \ ASN1_ITYPE_CHOICE,\ offsetof(stname,selname) ,\ tname##_ch_tt,\ sizeof(tname##_ch_tt) / sizeof(ASN1_TEMPLATE),\ NULL,\ sizeof(stname),\ #stname \ ASN1_ITEM_end(tname) #define ASN1_CHOICE_END_cb(stname, tname, selname) \ ;\ ASN1_ITEM_start(tname) \ ASN1_ITYPE_CHOICE,\ offsetof(stname,selname) ,\ tname##_ch_tt,\ sizeof(tname##_ch_tt) / sizeof(ASN1_TEMPLATE),\ &tname##_aux,\ sizeof(stname),\ #stname \ ASN1_ITEM_end(tname) /* This helps with the template wrapper form of ASN1_ITEM */ #define ASN1_EX_TEMPLATE_TYPE(flags, tag, name, type) { \ (flags), (tag), 0,\ #name, ASN1_ITEM_ref(type) } /* These help with SEQUENCE or CHOICE components */ /* used to declare other types */ #define ASN1_EX_TYPE(flags, tag, stname, field, type) { \ (flags), (tag), offsetof(stname, field),\ #field, ASN1_ITEM_ref(type) } /* used when the structure is combined with the parent */ #define ASN1_EX_COMBINE(flags, tag, type) { \ (flags)|ASN1_TFLG_COMBINE, (tag), 0, NULL, ASN1_ITEM_ref(type) } /* implicit and explicit helper macros */ #define ASN1_IMP_EX(stname, field, type, tag, ex) \ ASN1_EX_TYPE(ASN1_TFLG_IMPLICIT | ex, tag, stname, field, type) #define ASN1_EXP_EX(stname, field, type, tag, ex) \ ASN1_EX_TYPE(ASN1_TFLG_EXPLICIT | ex, tag, stname, field, type) /* Any defined by macros: the field used is in the table itself */ #ifndef OPENSSL_EXPORT_VAR_AS_FUNCTION #define ASN1_ADB_OBJECT(tblname) { ASN1_TFLG_ADB_OID, -1, 0, #tblname, (const(ASN1_ITEM)*)&(tblname##_adb) } #define ASN1_ADB_INTEGER(tblname) { ASN1_TFLG_ADB_INT, -1, 0, #tblname, (const(ASN1_ITEM)*)&(tblname##_adb) } #else #define ASN1_ADB_OBJECT(tblname) { ASN1_TFLG_ADB_OID, -1, 0, #tblname, tblname##_adb } #define ASN1_ADB_INTEGER(tblname) { ASN1_TFLG_ADB_INT, -1, 0, #tblname, tblname##_adb } #endif /* Plain simple type */ #define ASN1_SIMPLE(stname, field, type) ASN1_EX_TYPE(0,0, stname, field, type) /* OPTIONAL simple type */ #define ASN1_OPT(stname, field, type) ASN1_EX_TYPE(ASN1_TFLG_OPTIONAL, 0, stname, field, type) /* IMPLICIT tagged simple type */ #define ASN1_IMP(stname, field, type, tag) ASN1_IMP_EX(stname, field, type, tag, 0) /* IMPLICIT tagged OPTIONAL simple type */ #define ASN1_IMP_OPT(stname, field, type, tag) ASN1_IMP_EX(stname, field, type, tag, ASN1_TFLG_OPTIONAL) /* Same as above but EXPLICIT */ #define ASN1_EXP(stname, field, type, tag) ASN1_EXP_EX(stname, field, type, tag, 0) #define ASN1_EXP_OPT(stname, field, type, tag) ASN1_EXP_EX(stname, field, type, tag, ASN1_TFLG_OPTIONAL) /* SEQUENCE OF type */ #define ASN1_SEQUENCE_OF(stname, field, type) \ ASN1_EX_TYPE(ASN1_TFLG_SEQUENCE_OF, 0, stname, field, type) /* OPTIONAL SEQUENCE OF */ #define ASN1_SEQUENCE_OF_OPT(stname, field, type) \ ASN1_EX_TYPE(ASN1_TFLG_SEQUENCE_OF|ASN1_TFLG_OPTIONAL, 0, stname, field, type) /* Same as above but for SET OF */ #define ASN1_SET_OF(stname, field, type) \ ASN1_EX_TYPE(ASN1_TFLG_SET_OF, 0, stname, field, type) #define ASN1_SET_OF_OPT(stname, field, type) \ ASN1_EX_TYPE(ASN1_TFLG_SET_OF|ASN1_TFLG_OPTIONAL, 0, stname, field, type) /* Finally compound types of SEQUENCE, SET, IMPLICIT, EXPLICIT and OPTIONAL */ #define ASN1_IMP_SET_OF(stname, field, type, tag) \ ASN1_IMP_EX(stname, field, type, tag, ASN1_TFLG_SET_OF) #define ASN1_EXP_SET_OF(stname, field, type, tag) \ ASN1_EXP_EX(stname, field, type, tag, ASN1_TFLG_SET_OF) #define ASN1_IMP_SET_OF_OPT(stname, field, type, tag) \ ASN1_IMP_EX(stname, field, type, tag, ASN1_TFLG_SET_OF|ASN1_TFLG_OPTIONAL) #define ASN1_EXP_SET_OF_OPT(stname, field, type, tag) \ ASN1_EXP_EX(stname, field, type, tag, ASN1_TFLG_SET_OF|ASN1_TFLG_OPTIONAL) #define ASN1_IMP_SEQUENCE_OF(stname, field, type, tag) \ ASN1_IMP_EX(stname, field, type, tag, ASN1_TFLG_SEQUENCE_OF) #define ASN1_IMP_SEQUENCE_OF_OPT(stname, field, type, tag) \ ASN1_IMP_EX(stname, field, type, tag, ASN1_TFLG_SEQUENCE_OF|ASN1_TFLG_OPTIONAL) #define ASN1_EXP_SEQUENCE_OF(stname, field, type, tag) \ ASN1_EXP_EX(stname, field, type, tag, ASN1_TFLG_SEQUENCE_OF) #define ASN1_EXP_SEQUENCE_OF_OPT(stname, field, type, tag) \ ASN1_EXP_EX(stname, field, type, tag, ASN1_TFLG_SEQUENCE_OF|ASN1_TFLG_OPTIONAL) /* EXPLICIT using indefinite length constructed form */ #define ASN1_NDEF_EXP(stname, field, type, tag) \ ASN1_EXP_EX(stname, field, type, tag, ASN1_TFLG_NDEF) /* EXPLICIT OPTIONAL using indefinite length constructed form */ #define ASN1_NDEF_EXP_OPT(stname, field, type, tag) \ ASN1_EXP_EX(stname, field, type, tag, ASN1_TFLG_OPTIONAL|ASN1_TFLG_NDEF) /* Macros for the ASN1_ADB structure */ #define ASN1_ADB(name) \ static const ASN1_ADB_TABLE[] name##_adbtbl #ifndef OPENSSL_EXPORT_VAR_AS_FUNCTION #define ASN1_ADB_END(name, flags, field, app_table, def, none) \ ;\ static const ASN1_ADB name##_adb = {\ flags,\ offsetof(name, field),\ app_table,\ name##_adbtbl,\ sizeof(name##_adbtbl) / sizeof(ASN1_ADB_TABLE),\ def,\ none\ } #else #define ASN1_ADB_END(name, flags, field, app_table, def, none) \ ;\ static const(ASN1_ITEM)* name##_adb() \ { \ static const ASN1_ADB internal_adb = \ {\ flags,\ offsetof(name, field),\ app_table,\ name##_adbtbl,\ sizeof(name##_adbtbl) / sizeof(ASN1_ADB_TABLE),\ def,\ none\ }; \ return (const(ASN1_ITEM)*) &internal_adb; \ } \ void dummy_function() #endif #define ADB_ENTRY(val, template) {val, template} #define ASN1_ADB_TEMPLATE(name) \ static const ASN1_TEMPLATE name##_tt +/ /* This is the ASN1 template structure that defines * a wrapper round the actual type. It determines the * actual position of the field in the value structure, * various flags such as OPTIONAL and the field name. */ struct ASN1_TEMPLATE_st { c_ulong flags; /* Various flags */ c_long tag; /* tag, not used if no tagging */ c_ulong offset; /* Offset of this field in structure */ version (NO_ASN1_FIELD_NAMES) {} else { const(char)* field_name; /* Field name */ } ASN1_ITEM_EXP* item; /* Relevant ASN1_ITEM or ASN1_ADB */ }; /* Macro to extract ASN1_ITEM and ASN1_ADB pointer from ASN1_TEMPLATE */ auto ASN1_TEMPLATE_item()(ASN1_TEMPLATE_st* t) { return (t.item_ptr); } auto ASN1_TEMPLATE_adb()(ASN1_TEMPLATE_st* t) { return (t.item_ptr); } alias ASN1_ADB_TABLE_st ASN1_ADB_TABLE; alias ASN1_ADB_st ASN1_ADB; struct ASN1_ADB_st { c_ulong flags; /* Various flags */ c_ulong offset; /* Offset of selector field */ STACK_OF!(ASN1_ADB_TABLE) **app_items; /* Application defined items */ const(ASN1_ADB_TABLE)* tbl; /* Table of possible types */ c_long tblcount; /* Number of entries in tbl */ const(ASN1_TEMPLATE)* default_tt; /* Type to use if no match */ const(ASN1_TEMPLATE)* null_tt; /* Type to use if selector is NULL */ }; struct ASN1_ADB_TABLE_st { c_long value; /* NID for an object or value for an int */ const ASN1_TEMPLATE tt; /* item for this value */ }; /* template flags */ /* Field is optional */ enum ASN1_TFLG_OPTIONAL = (0x1); /* Field is a SET OF */ enum ASN1_TFLG_SET_OF = (0x1 << 1); /* Field is a SEQUENCE OF */ enum ASN1_TFLG_SEQUENCE_OF = (0x2 << 1); /* Special case: this refers to a SET OF that * will be sorted into DER order when encoded* and* * the corresponding STACK will be modified to match * the new order. */ enum ASN1_TFLG_SET_ORDER = (0x3 << 1); /* Mask for SET OF or SEQUENCE OF */ enum ASN1_TFLG_SK_MASK = (0x3 << 1); /* These flags mean the tag should be taken from the * tag field. If EXPLICIT then the underlying type * is used for the inner tag. */ /* IMPLICIT tagging */ enum ASN1_TFLG_IMPTAG = (0x1 << 3); /* EXPLICIT tagging, inner tag from underlying type */ enum ASN1_TFLG_EXPTAG = (0x2 << 3); enum ASN1_TFLG_TAG_MASK = (0x3 << 3); /* context specific IMPLICIT */ enum ASN1_TFLG_IMPLICIT = ASN1_TFLG_IMPTAG|ASN1_TFLG_CONTEXT; /* context specific EXPLICIT */ enum ASN1_TFLG_EXPLICIT = ASN1_TFLG_EXPTAG|ASN1_TFLG_CONTEXT; /* If tagging is in force these determine the * type of tag to use. Otherwise the tag is * determined by the underlying type. These * values reflect the actual octet format. */ /* Universal tag */ enum ASN1_TFLG_UNIVERSAL = (0x0<<6); /* Application tag */ enum ASN1_TFLG_APPLICATION = (0x1<<6); /* Context specific tag */ enum ASN1_TFLG_CONTEXT = (0x2<<6); /* Private tag */ enum ASN1_TFLG_PRIVATE = (0x3<<6); enum ASN1_TFLG_TAG_CLASS = (0x3<<6); /* These are for ANY DEFINED BY type. In this case * the 'item' field points to an ASN1_ADB structure * which contains a table of values to decode the * relevant type */ enum ASN1_TFLG_ADB_MASK = (0x3<<8); enum ASN1_TFLG_ADB_OID = (0x1<<8); enum ASN1_TFLG_ADB_INT = (0x1<<9); /* This flag means a parent structure is passed * instead of the field: this is useful is a * SEQUENCE is being combined with a CHOICE for * example. Since this means the structure and * item name will differ we need to use the * ASN1_CHOICE_END_name() macro for example. */ enum ASN1_TFLG_COMBINE = (0x1<<10); /* This flag when present in a SEQUENCE OF, SET OF * or EXPLICIT causes indefinite length constructed * encoding to be used if required. */ enum ASN1_TFLG_NDEF = (0x1<<11); /* This is the actual ASN1 item itself */ struct ASN1_ITEM_st { char itype; /* The item type, primitive, SEQUENCE, CHOICE or extern */ c_long utype; /* underlying type */ const(ASN1_TEMPLATE)* templates; /* If SEQUENCE or CHOICE this contains the contents */ c_long tcount; /* Number of templates if SEQUENCE or CHOICE */ const(void)* funcs; /* functions that handle this type */ c_long size; /* Structure size (usually)*/ version (NO_ASN1_FIELD_NAMES) {} else { const(char)* sname; /* Structure name */ } }; /* These are values for the itype field and * determine how the type is interpreted. * * For PRIMITIVE types the underlying type * determines the behaviour if items is NULL. * * Otherwise templates must contain a single * template and the type is treated in the * same way as the type specified in the template. * * For SEQUENCE types the templates field points * to the members, the size field is the * structure size. * * For CHOICE types the templates field points * to each possible member (typically a union) * and the 'size' field is the offset of the * selector. * * The 'funcs' field is used for application * specific functions. * * For COMPAT types the funcs field gives a * set of functions that handle this type, this * supports the old d2i, i2d convention. * * The EXTERN type uses a new style d2i/i2d. * The new style should be used where possible * because it avoids things like the d2i IMPLICIT * hack. * * MSTRING is a multiple string type, it is used * for a CHOICE of character strings where the * actual strings all occupy an ASN1_STRING * structure. In this case the 'utype' field * has a special meaning, it is used as a mask * of acceptable types using the B_ASN1 constants. * * NDEF_SEQUENCE is the same as SEQUENCE except * that it will use indefinite length constructed * encoding if requested. * */ enum ASN1_ITYPE_PRIMITIVE = 0x0; enum ASN1_ITYPE_SEQUENCE = 0x1; enum ASN1_ITYPE_CHOICE = 0x2; enum ASN1_ITYPE_COMPAT = 0x3; enum ASN1_ITYPE_EXTERN = 0x4; enum ASN1_ITYPE_MSTRING = 0x5; enum ASN1_ITYPE_NDEF_SEQUENCE = 0x6; /* Cache for ASN1 tag and length, so we * don't keep re-reading it for things * like CHOICE */ struct ASN1_TLC_st{ char valid; /* Values below are valid */ int ret; /* return value */ c_long plen; /* length */ int ptag; /* class value */ int pclass; /* class value */ int hdrlen; /* header length */ }; /* Typedefs for ASN1 function pointers */ alias typeof(*(ExternC!(ASN1_VALUE* function())).init) ASN1_new_func; alias typeof(*(ExternC!(void function(ASN1_VALUE* a))).init) ASN1_free_func; alias typeof(*(ExternC!(ASN1_VALUE* function(ASN1_VALUE** a, const(ubyte)** in_, c_long length))).init) ASN1_d2i_func; alias typeof(*(ExternC!(int function(ASN1_VALUE* a, ubyte** in_))).init) ASN1_i2d_func; alias typeof(*(ExternC!(int function(ASN1_VALUE** pval, const(ubyte)** in_, c_long len, const(ASN1_ITEM)* it, int tag, int aclass, char opt, ASN1_TLC* ctx))).init) ASN1_ex_d2i; alias typeof(*(ExternC!(int function(ASN1_VALUE** pval, ubyte** out_, const(ASN1_ITEM)* it, int tag, int aclass))).init) ASN1_ex_i2d; alias typeof(*(ExternC!(int function(ASN1_VALUE** pval, const(ASN1_ITEM)* it))).init) ASN1_ex_new_func; alias typeof(*(ExternC!(void function(ASN1_VALUE** pval, const(ASN1_ITEM)* it))).init) ASN1_ex_free_func; alias typeof(*(ExternC!(int function(BIO* out_, ASN1_VALUE** pval, int indent, const(char)* fname, const(ASN1_PCTX)* pctx))).init) ASN1_ex_print_func; alias typeof(*(ExternC!(int function(ASN1_VALUE** pval, ubyte* cont, int* putype, const(ASN1_ITEM)* it))).init) ASN1_primitive_i2c; alias typeof(*(ExternC!(int function(ASN1_VALUE** pval, const(ubyte)* cont, int len, int utype, char* free_cont, const(ASN1_ITEM)* it))).init) ASN1_primitive_c2i; alias typeof(*(ExternC!(int function(BIO* out_, ASN1_VALUE** pval, const(ASN1_ITEM)* it, int indent, const(ASN1_PCTX)* pctx))).init) ASN1_primitive_print; struct ASN1_COMPAT_FUNCS_st { ASN1_new_func* asn1_new; ASN1_free_func* asn1_free; ASN1_d2i_func* asn1_d2i; ASN1_i2d_func* asn1_i2d; } alias ASN1_COMPAT_FUNCS_st ASN1_COMPAT_FUNCS; struct ASN1_EXTERN_FUNCS_st { void* app_data; ASN1_ex_new_func* asn1_ex_new; ASN1_ex_free_func* asn1_ex_free; ASN1_ex_free_func* asn1_ex_clear; ASN1_ex_d2i* asn1_ex_d2i; ASN1_ex_i2d* asn1_ex_i2d; ASN1_ex_print_func* asn1_ex_print; } alias ASN1_EXTERN_FUNCS_st ASN1_EXTERN_FUNCS; struct ASN1_PRIMITIVE_FUNCS_st { void* app_data; c_ulong flags; ASN1_ex_new_func* prim_new; ASN1_ex_free_func* prim_free; ASN1_ex_free_func* prim_clear; ASN1_primitive_c2i* prim_c2i; ASN1_primitive_i2c* prim_i2c; ASN1_primitive_print* prim_print; } alias ASN1_PRIMITIVE_FUNCS_st ASN1_PRIMITIVE_FUNCS; /* This is the ASN1_AUX structure: it handles various * miscellaneous requirements. For example the use of * reference counts and an informational callback. * * The "informational callback" is called at various * points during the ASN1 encoding and decoding. It can * be used to provide minor customisation of the structures * used. This is most useful where the supplied routines ** almost* do the right thing but need some extra help * at a few points. If the callback returns zero then * it is assumed a fatal error has occurred and the * main operation should be abandoned. * * If major changes in the default behaviour are required * then an external type is more appropriate. */ alias typeof(*(ExternC!(int function(int operation, ASN1_VALUE** in_, const(ASN1_ITEM)* it, void* exarg))).init) ASN1_aux_cb; struct ASN1_AUX_st { void* app_data; int flags; int ref_offset; /* Offset of reference value */ int ref_lock; /* Lock type to use */ ASN1_aux_cb* asn1_cb; int enc_offset; /* Offset of ASN1_ENCODING structure */ } alias ASN1_AUX_st ASN1_AUX; /* For print related callbacks exarg points to this structure */ struct ASN1_PRINT_ARG_st { BIO* out_; int indent; const(ASN1_PCTX)* pctx; } alias ASN1_PRINT_ARG_st ASN1_PRINT_ARG; /* For streaming related callbacks exarg points to this structure */ struct ASN1_STREAM_ARG_st { /* BIO to stream through */ BIO* out_; /* BIO with filters appended */ BIO* ndef_bio; /* Streaming I/O boundary */ ubyte** boundary; } alias ASN1_STREAM_ARG_st ASN1_STREAM_ARG; /* Flags in ASN1_AUX */ /* Use a reference count */ enum ASN1_AFLG_REFCOUNT = 1; /* Save the encoding of structure (useful for signatures) */ enum ASN1_AFLG_ENCODING = 2; /* The Sequence length is invalid */ enum ASN1_AFLG_BROKEN = 4; /* operation values for asn1_cb */ enum ASN1_OP_NEW_PRE = 0; enum ASN1_OP_NEW_POST = 1; enum ASN1_OP_FREE_PRE = 2; enum ASN1_OP_FREE_POST = 3; enum ASN1_OP_D2I_PRE = 4; enum ASN1_OP_D2I_POST = 5; enum ASN1_OP_I2D_PRE = 6; enum ASN1_OP_I2D_POST = 7; enum ASN1_OP_PRINT_PRE = 8; enum ASN1_OP_PRINT_POST = 9; enum ASN1_OP_STREAM_PRE = 10; enum ASN1_OP_STREAM_POST = 11; enum ASN1_OP_DETACHED_PRE = 12; enum ASN1_OP_DETACHED_POST = 13; /+ FIXME: Not yet ported. /* Macro to implement a primitive type */ #define IMPLEMENT_ASN1_TYPE(stname) IMPLEMENT_ASN1_TYPE_ex(stname, stname, 0) #define IMPLEMENT_ASN1_TYPE_ex(itname, vname, ex) \ ASN1_ITEM_start(itname) \ ASN1_ITYPE_PRIMITIVE, V_##vname, NULL, 0, NULL, ex, #itname \ ASN1_ITEM_end(itname) /* Macro to implement a multi string type */ #define IMPLEMENT_ASN1_MSTRING(itname, mask) \ ASN1_ITEM_start(itname) \ ASN1_ITYPE_MSTRING, mask, NULL, 0, NULL, sizeof(ASN1_STRING), #itname \ ASN1_ITEM_end(itname) /* Macro to implement an ASN1_ITEM in terms of old style funcs */ #define IMPLEMENT_COMPAT_ASN1(sname) IMPLEMENT_COMPAT_ASN1_type(sname, V_ASN1_SEQUENCE) #define IMPLEMENT_COMPAT_ASN1_type(sname, tag) \ static const ASN1_COMPAT_FUNCS sname##_ff = { \ (ASN1_new_func*)sname##_new, \ (ASN1_free_func*)sname##_free, \ (ASN1_d2i_func*)d2i_##sname, \ (ASN1_i2d_func*)i2d_##sname, \ }; \ ASN1_ITEM_start(sname) \ ASN1_ITYPE_COMPAT, \ tag, \ NULL, \ 0, \ &sname##_ff, \ 0, \ #sname \ ASN1_ITEM_end(sname) #define IMPLEMENT_EXTERN_ASN1(sname, tag, fptrs) \ ASN1_ITEM_start(sname) \ ASN1_ITYPE_EXTERN, \ tag, \ NULL, \ 0, \ &fptrs, \ 0, \ #sname \ ASN1_ITEM_end(sname) /* Macro to implement standard functions in terms of ASN1_ITEM structures */ #define IMPLEMENT_ASN1_FUNCTIONS(stname) IMPLEMENT_ASN1_FUNCTIONS_fname(stname, stname, stname) #define IMPLEMENT_ASN1_FUNCTIONS_name(stname, itname) IMPLEMENT_ASN1_FUNCTIONS_fname(stname, itname, itname) #define IMPLEMENT_ASN1_FUNCTIONS_ENCODE_name(stname, itname) \ IMPLEMENT_ASN1_FUNCTIONS_ENCODE_fname(stname, itname, itname) #define IMPLEMENT_STATIC_ASN1_ALLOC_FUNCTIONS(stname) \ IMPLEMENT_ASN1_ALLOC_FUNCTIONS_pfname(static, stname, stname, stname) #define IMPLEMENT_ASN1_ALLOC_FUNCTIONS(stname) \ IMPLEMENT_ASN1_ALLOC_FUNCTIONS_fname(stname, stname, stname) #define IMPLEMENT_ASN1_ALLOC_FUNCTIONS_pfname(pre, stname, itname, fname) \ pre stname* fname##_new() \ { \ return (stname*)ASN1_item_new(ASN1_ITEM_rptr(itname)); \ } \ pre void fname##_free(stname* a) \ { \ ASN1_item_free((ASN1_VALUE*)a, ASN1_ITEM_rptr(itname)); \ } #define IMPLEMENT_ASN1_ALLOC_FUNCTIONS_fname(stname, itname, fname) \ stname* fname##_new() \ { \ return (stname*)ASN1_item_new(ASN1_ITEM_rptr(itname)); \ } \ void fname##_free(stname* a) \ { \ ASN1_item_free((ASN1_VALUE*)a, ASN1_ITEM_rptr(itname)); \ } #define IMPLEMENT_ASN1_FUNCTIONS_fname(stname, itname, fname) \ IMPLEMENT_ASN1_ENCODE_FUNCTIONS_fname(stname, itname, fname) \ IMPLEMENT_ASN1_ALLOC_FUNCTIONS_fname(stname, itname, fname) #define IMPLEMENT_ASN1_ENCODE_FUNCTIONS_fname(stname, itname, fname) \ stname* d2i_##fname(stname** a, const(ubyte)** in_, c_long len) \ { \ return (stname*)ASN1_item_d2i((ASN1_VALUE**)a, in_, len, ASN1_ITEM_rptr(itname));\ } \ int i2d_##fname(stname* a, ubyte** out_) \ { \ return ASN1_item_i2d((ASN1_VALUE*)a, out_, ASN1_ITEM_rptr(itname));\ } #define IMPLEMENT_ASN1_NDEF_FUNCTION(stname) \ int i2d_##stname##_NDEF(stname* a, ubyte** out_) \ { \ return ASN1_item_ndef_i2d((ASN1_VALUE*)a, out_, ASN1_ITEM_rptr(stname));\ } /* This includes evil casts to remove const: they will go away when full * ASN1 constification is done. */ #define IMPLEMENT_ASN1_ENCODE_FUNCTIONS_const_fname(stname, itname, fname) \ stname* d2i_##fname(stname** a, const(ubyte)** in_, c_long len) \ { \ return (stname*)ASN1_item_d2i((ASN1_VALUE**)a, in_, len, ASN1_ITEM_rptr(itname));\ } \ int i2d_##fname(const(stname)* a, ubyte** out_) \ { \ return ASN1_item_i2d((ASN1_VALUE*)a, out_, ASN1_ITEM_rptr(itname));\ } #define IMPLEMENT_ASN1_DUP_FUNCTION(stname) \ stname* stname##_dup(stname* x) \ { \ return ASN1_item_dup(ASN1_ITEM_rptr(stname), x); \ } #define IMPLEMENT_ASN1_PRINT_FUNCTION(stname) \ IMPLEMENT_ASN1_PRINT_FUNCTION_fname(stname, stname, stname) #define IMPLEMENT_ASN1_PRINT_FUNCTION_fname(stname, itname, fname) \ int fname##_print_ctx(BIO* out_, stname* x, int indent, \ const(ASN1_PCTX)* pctx) \ { \ return ASN1_item_print(out, (ASN1_VALUE*)x, indent, \ ASN1_ITEM_rptr(itname), pctx); \ } #define IMPLEMENT_ASN1_FUNCTIONS_const(name) \ IMPLEMENT_ASN1_FUNCTIONS_const_fname(name, name, name) #define IMPLEMENT_ASN1_FUNCTIONS_const_fname(stname, itname, fname) \ IMPLEMENT_ASN1_ENCODE_FUNCTIONS_const_fname(stname, itname, fname) \ IMPLEMENT_ASN1_ALLOC_FUNCTIONS_fname(stname, itname, fname) +/ /* external definitions for primitive types */ mixin(DECLARE_ASN1_ITEM!"ASN1_BOOLEAN"); mixin(DECLARE_ASN1_ITEM!"ASN1_TBOOLEAN"); mixin(DECLARE_ASN1_ITEM!"ASN1_FBOOLEAN"); mixin(DECLARE_ASN1_ITEM!"ASN1_SEQUENCE"); mixin(DECLARE_ASN1_ITEM!"CBIGNUM"); mixin(DECLARE_ASN1_ITEM!"BIGNUM"); mixin(DECLARE_ASN1_ITEM!"LONG"); mixin(DECLARE_ASN1_ITEM!"ZLONG"); /+mixin DECLARE_STACK_OF!(ASN1_VALUE);+/ /* Functions used internally by the ASN1 code */ int ASN1_item_ex_new(ASN1_VALUE** pval, const(ASN1_ITEM)* it); void ASN1_item_ex_free(ASN1_VALUE** pval, const(ASN1_ITEM)* it); int ASN1_template_new(ASN1_VALUE** pval, const(ASN1_TEMPLATE)* tt); int ASN1_primitive_new(ASN1_VALUE** pval, const(ASN1_ITEM)* it); void ASN1_template_free(ASN1_VALUE** pval, const(ASN1_TEMPLATE)* tt); int ASN1_template_d2i(ASN1_VALUE** pval, const(ubyte)** in_, c_long len, const(ASN1_TEMPLATE)* tt); int ASN1_item_ex_d2i(ASN1_VALUE** pval, const(ubyte)** in_, c_long len, const(ASN1_ITEM)* it, int tag, int aclass, char opt, ASN1_TLC* ctx); int ASN1_item_ex_i2d(ASN1_VALUE** pval, ubyte** out_, const(ASN1_ITEM)* it, int tag, int aclass); int ASN1_template_i2d(ASN1_VALUE** pval, ubyte** out_, const(ASN1_TEMPLATE)* tt); void ASN1_primitive_free(ASN1_VALUE** pval, const(ASN1_ITEM)* it); int asn1_ex_i2c(ASN1_VALUE** pval, ubyte* cont, int* putype, const(ASN1_ITEM)* it); int asn1_ex_c2i(ASN1_VALUE** pval, const(ubyte)* cont, int len, int utype, char* free_cont, const(ASN1_ITEM)* it); int asn1_get_choice_selector(ASN1_VALUE** pval, const(ASN1_ITEM)* it); int asn1_set_choice_selector(ASN1_VALUE** pval, int value, const(ASN1_ITEM)* it); ASN1_VALUE** asn1_get_field_ptr(ASN1_VALUE** pval, const(ASN1_TEMPLATE)* tt); const(ASN1_TEMPLATE)* asn1_do_adb(ASN1_VALUE** pval, const(ASN1_TEMPLATE)* tt, int nullerr); int asn1_do_lock(ASN1_VALUE** pval, int op, const(ASN1_ITEM)* it); void asn1_enc_init(ASN1_VALUE** pval, const(ASN1_ITEM)* it); void asn1_enc_free(ASN1_VALUE** pval, const(ASN1_ITEM)* it); int asn1_enc_restore(int* len, ubyte** out_, ASN1_VALUE** pval, const(ASN1_ITEM)* it); int asn1_enc_save(ASN1_VALUE** pval, const(ubyte)* in_, int inlen, const(ASN1_ITEM)* it);