/** @file * IPRT - ASN.1 Code Generator, One Pass. */ /* * Copyright (C) 2006-2020 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. * * The contents of this file may alternatively be used under the terms * of the Common Development and Distribution License Version 1.0 * (CDDL) only, as it comes in the "COPYING.CDDL" file of the * VirtualBox OSE distribution, in which case the provisions of the * CDDL are applicable instead of those of the GPL. * * You may elect to license modified versions of this file under the * terms and conditions of either the GPL or the CDDL or both. */ #ifndef ___iprt_asn1_generator_pass_h /* (special, only part of the file) */ #define ___iprt_asn1_generator_pass_h #include #include /** @def RTASN1TMPL_MEMBER_OPT_ANY * Used for optional entries without any specific type at the end of a * structure. * * For example PolicyQualifierInfo's qualifier member which is defined as: * ANY DEFINED BY policyQualifierId * * Defaults to RTASN1TMPL_MEMBER_EX. */ /** @def RTASN1TMPL_MEMBER_OPT_ITAG_EX * Optional member with implict tag, extended version. * * This is what all the other RTASN1TMPL_MEMBER_OPT_ITAG* macros defere to. */ /** @def RTASN1TMPL_MEMBER_OPT_ITAG_CP * Optional member of a typical primitive type with an implicit context tag. * * Examples of this can be found in AuthorityKeyIdentifier where the first and * last member are primitive types (normally anyways).: * keyIdentifier [1] OCTET STRING OPTIONAL, * authorityCertSerialNumber [3] INTEGER OPTIONAL */ /** @def RTASN1TMPL_MEMBER_OPT_ITAG_UC * Optional member of a constructed type from the universal tag class. */ /** @def RTASN1TMPL_MEMBER_OPT_ITAG_UP * Optional member of a primitive type from the universal tag class. */ /** @name Expansion Passes (RTASN1TMPL_PASS values) * @{ */ #define RTASN1TMPL_PASS_INTERNAL_HEADER 1 #define RTASN1TMPL_PASS_XTAG 2 #define RTASN1TMPL_PASS_VTABLE 3 #define RTASN1TMPL_PASS_ENUM 4 #define RTASN1TMPL_PASS_DELETE 5 #define RTASN1TMPL_PASS_COMPARE 6 #define RTASN1TMPL_PASS_CHECK_SANITY 8 #define RTASN1TMPL_PASS_INIT 16 #define RTASN1TMPL_PASS_CLONE 17 #define RTASN1TMPL_PASS_SETTERS_1 18 #define RTASN1TMPL_PASS_SETTERS_2 19 #define RTASN1TMPL_PASS_ARRAY 20 #define RTASN1TMPL_PASS_DECODE 24 /** @} */ /** @name ITAG clues * @{ */ #define RTASN1TMPL_ITAG_F_CC 1 /**< context, constructed. */ #define RTASN1TMPL_ITAG_F_CP 2 /**< context, probably primary. (w/ numeric value) */ #define RTASN1TMPL_ITAG_F_UP 3 /**< universal, probably primary. (w/ ASN1_TAG_XXX value) */ #define RTASN1TMPL_ITAG_F_UC 4 /**< universal, constructed. (w/ ASN1_TAG_XXX value) */ /** @} */ /** Expands the ITAG clues into tag flag and tag class. */ #define RTASN1TMPL_ITAG_F_EXPAND(a_fClue) \ ( a_fClue == RTASN1TMPL_ITAG_F_CC ? (ASN1_TAGCLASS_CONTEXT | ASN1_TAGFLAG_CONSTRUCTED ) \ : a_fClue == RTASN1TMPL_ITAG_F_CP ? (ASN1_TAGCLASS_CONTEXT | ASN1_TAGFLAG_PRIMITIVE) \ : a_fClue == RTASN1TMPL_ITAG_F_UP ? (ASN1_TAGCLASS_UNIVERSAL | ASN1_TAGFLAG_PRIMITIVE) \ : a_fClue == RTASN1TMPL_ITAG_F_UC ? (ASN1_TAGCLASS_UNIVERSAL | ASN1_TAGFLAG_CONSTRUCTED) \ : 0 ) #define RTASN1TMPL_SEMICOLON_DUMMY() typedef unsigned RTASN1TMPLSEMICOLONDUMMY #endif /* !___iprt_asn1_generator_pass_h */ #if RTASN1TMPL_PASS == RTASN1TMPL_PASS_INTERNAL_HEADER /* * * Internal header file. * */ # define RTASN1TMPL_BEGIN_COMMON() extern DECL_HIDDEN_DATA(RTASN1COREVTABLE const) RT_CONCAT3(g_,RTASN1TMPL_INT_NAME,_Vtable) # define RTASN1TMPL_BEGIN_SEQCORE() RTASN1TMPL_BEGIN_COMMON() # define RTASN1TMPL_BEGIN_SETCORE() RTASN1TMPL_BEGIN_COMMON() # define RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, a_Constraints) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_MEMBER_OPT_XTAG_EX(a_TnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_uTag, a_Constraints) \ extern "C" DECL_HIDDEN_DATA(RTASN1COREVTABLE const) RT_CONCAT5(g_,RTASN1TMPL_INT_NAME,_XTAG_,a_Name,_Vtable) # define RTASN1TMPL_MEMBER_DYN_BEGIN(a_enmType, a_enmMembNm, a_Allocation) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_MEMBER_DYN_END(a_enmType, a_enmMembNm, a_Allocation) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_END_SEQCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_END_SETCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_PCHOICE() RTASN1TMPL_BEGIN_COMMON() # define RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, a_fClue, a_Constraints) \ RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_PCHOICE_XTAG_EX(a_uTag, a_enmChoice, a_PtrTnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_Constraints) \ extern "C" DECL_HIDDEN_DATA(RTASN1COREVTABLE const) RT_CONCAT5(g_,RTASN1TMPL_INT_NAME,_PCHOICE_XTAG_,a_Name,_Vtable) # define RTASN1TMPL_END_PCHOICE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_SEQ_OF(a_ItemType, a_ItemApi) RTASN1TMPL_BEGIN_COMMON() # define RTASN1TMPL_SET_OF(a_ItemType, a_ItemApi) RTASN1TMPL_BEGIN_COMMON() #elif RTASN1TMPL_PASS == RTASN1TMPL_PASS_XTAG /* * * Generate a vtable and associated methods for explicitly tagged items (XTAG). * * These turned out to be a little problematic during encoding since there are * two tags, the first encapsulating the second, thus the enumeration has to be * nested or we cannot calculate the size of the first tag. * * */ # define RTASN1TMPL_BEGIN_COMMON() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_SEQCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_SETCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, a_Constraints) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_MEMBER_DYN_BEGIN(a_enmType, a_enmMembNm, a_Allocation) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_MEMBER_DYN_END(a_enmType, a_enmMembNm, a_Allocation) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_MEMBER_OPT_XTAG_EX(a_TnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_uTag, a_Constraints) \ /* This is the method we need to make it work. */ \ static DECLCALLBACK(int) RT_CONCAT4(RTASN1TMPL_INT_NAME,_XTAG_,a_Name,_Enum)(PRTASN1CORE pThisCore, \ PFNRTASN1ENUMCALLBACK pfnCallback, \ uint32_t uDepth, void *pvUser) \ { \ RTASN1TMPL_TYPE *pThis = RT_FROM_MEMBER(pThisCore, RTASN1TMPL_TYPE, a_TnNm.a_CtxTagN); \ if (RTASN1CORE_IS_PRESENT(&pThis->a_TnNm.a_CtxTagN.Asn1Core)) \ return pfnCallback(RT_CONCAT(a_Api,_GetAsn1Core)(&pThis->a_TnNm.a_Name), #a_TnNm "." #a_Name, uDepth + 1, pvUser); \ return VINF_SUCCESS; \ } \ /* The reminder of the methods shouldn't normally be needed, just stub them. */ \ static DECLCALLBACK(void) RT_CONCAT4(RTASN1TMPL_INT_NAME,_XTAG_,a_Name,_Delete)(PRTASN1CORE pThisCore) \ { AssertFailed(); RT_NOREF_PV(pThisCore); } \ static DECLCALLBACK(int) RT_CONCAT4(RTASN1TMPL_INT_NAME,_XTAG_,a_Name,_Clone)(PRTASN1CORE pThisCore, PCRTASN1CORE pSrcCore, \ PCRTASN1ALLOCATORVTABLE pAllocator) \ { AssertFailed(); RT_NOREF_PV(pThisCore); RT_NOREF_PV(pSrcCore); RT_NOREF_PV(pAllocator); return VERR_INTERNAL_ERROR_2; } \ static DECLCALLBACK(int) RT_CONCAT4(RTASN1TMPL_INT_NAME,_XTAG_,a_Name,_Compare)(PCRTASN1CORE pLeftCore, \ PCRTASN1CORE pRightCore) \ { AssertFailed(); RT_NOREF_PV(pLeftCore); RT_NOREF_PV(pRightCore); return VERR_INTERNAL_ERROR_2; } \ static DECLCALLBACK(int) RT_CONCAT4(RTASN1TMPL_INT_NAME,_XTAG_,a_Name,_CheckSanity)(PCRTASN1CORE pThisCore, uint32_t fFlags, \ PRTERRINFO pErrInfo, const char *pszErrorTag) \ { AssertFailed(); RT_NOREF_PV(pThisCore); RT_NOREF_PV(fFlags); RT_NOREF_PV(pErrInfo); RT_NOREF_PV(pszErrorTag); \ return VERR_INTERNAL_ERROR_2; } \ DECL_HIDDEN_CONST(RTASN1COREVTABLE const) RT_CONCAT5(g_,RTASN1TMPL_INT_NAME,_XTAG_,a_Name,_Vtable) = \ { \ /* When the Asn1Core is at the start of the structure, we can reuse the _Delete and _Enum APIs here. */ \ /* .pszName = */ RT_XSTR(RTASN1TMPL_INT_NAME) "_XTAG_" RT_XSTR(a_Name), \ /* .cb = */ RT_SIZEOFMEMB(RTASN1TMPL_TYPE, a_TnNm), \ /* .uDefaultTag = */ a_uTag, \ /* .fDefaultClass = */ ASN1_TAGCLASS_CONTEXT, \ /* .uReserved = */ 0, \ RT_CONCAT4(RTASN1TMPL_INT_NAME,_XTAG_,a_Name,_Delete), \ RT_CONCAT4(RTASN1TMPL_INT_NAME,_XTAG_,a_Name,_Enum), \ RT_CONCAT4(RTASN1TMPL_INT_NAME,_XTAG_,a_Name,_Clone), \ RT_CONCAT4(RTASN1TMPL_INT_NAME,_XTAG_,a_Name,_Compare), \ RT_CONCAT4(RTASN1TMPL_INT_NAME,_XTAG_,a_Name,_CheckSanity), \ /*.pfnEncodePrep */ NULL, \ /*.pfnEncodeWrite */ NULL \ } # define RTASN1TMPL_END_SEQCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_END_SETCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_PCHOICE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, a_fClue, a_Constraints) \ RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_PCHOICE_XTAG_EX(a_uTag, a_enmChoice, a_PtrTnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_Constraints) \ /* This is the method we need to make it work. */ \ static DECLCALLBACK(int) RT_CONCAT4(RTASN1TMPL_INT_NAME,_PC_XTAG_,a_Name,_Enum)(PRTASN1CORE pThisCore, \ PFNRTASN1ENUMCALLBACK pfnCallback, \ uint32_t uDepth, void *pvUser) \ { \ if (RTASN1CORE_IS_PRESENT(pThisCore)) \ { \ /** @todo optimize this one day, possibly change the PCHOICE+XTAG representation. */ \ RTASN1TMPL_TYPE Tmp; \ *(PRTASN1CORE *)&Tmp.a_PtrTnNm = pThisCore; \ Assert(&Tmp.a_PtrTnNm->a_CtxTagN.Asn1Core == pThisCore); \ return pfnCallback(RT_CONCAT(a_Api,_GetAsn1Core)(&Tmp.a_PtrTnNm->a_Name), "T" #a_uTag "." #a_Name, uDepth + 1, pvUser); \ } \ return VINF_SUCCESS; \ } \ /* The reminder of the methods shouldn't normally be needed, just stub them. */ \ static DECLCALLBACK(void) RT_CONCAT4(RTASN1TMPL_INT_NAME,_PC_XTAG_,a_Name,_Delete)(PRTASN1CORE pThisCore) \ { AssertFailed(); RT_NOREF_PV(pThisCore); } \ static DECLCALLBACK(int) RT_CONCAT4(RTASN1TMPL_INT_NAME,_PC_XTAG_,a_Name,_Clone)(PRTASN1CORE pThisCore, PCRTASN1CORE pSrcCore, \ PCRTASN1ALLOCATORVTABLE pAllocator) \ { AssertFailed(); RT_NOREF_PV(pThisCore); RT_NOREF_PV(pSrcCore); RT_NOREF_PV(pAllocator); return VERR_INTERNAL_ERROR_3; } \ static DECLCALLBACK(int) RT_CONCAT4(RTASN1TMPL_INT_NAME,_PC_XTAG_,a_Name,_Compare)(PCRTASN1CORE pLeftCore, \ PCRTASN1CORE pRightCore) \ { AssertFailed(); RT_NOREF_PV(pLeftCore); RT_NOREF_PV(pRightCore); return VERR_INTERNAL_ERROR_3; } \ static DECLCALLBACK(int) RT_CONCAT4(RTASN1TMPL_INT_NAME,_PC_XTAG_,a_Name,_CheckSanity)(PCRTASN1CORE pThisCore, uint32_t fFlags, \ PRTERRINFO pErrInfo, const char *pszErrorTag) \ { AssertFailed(); RT_NOREF_PV(pThisCore); RT_NOREF_PV(fFlags); RT_NOREF_PV(pErrInfo); RT_NOREF_PV(pszErrorTag); \ return VERR_INTERNAL_ERROR_3; } \ DECL_HIDDEN_CONST(RTASN1COREVTABLE const) RT_CONCAT5(g_,RTASN1TMPL_INT_NAME,_PCHOICE_XTAG_,a_Name,_Vtable) = \ { \ /* When the Asn1Core is at the start of the structure, we can reuse the _Delete and _Enum APIs here. */ \ /* .pszName = */ RT_XSTR(RTASN1TMPL_INT_NAME) "_PCHOICE_XTAG_" RT_XSTR(a_Name), \ /* .cb = */ sizeof(*((RTASN1TMPL_TYPE *)(void *)0)->a_PtrTnNm), \ /* .uDefaultTag = */ a_uTag, \ /* .fDefaultClass = */ ASN1_TAGCLASS_CONTEXT, \ /* .uReserved = */ 0, \ RT_CONCAT4(RTASN1TMPL_INT_NAME,_PC_XTAG_,a_Name,_Delete), \ RT_CONCAT4(RTASN1TMPL_INT_NAME,_PC_XTAG_,a_Name,_Enum), \ RT_CONCAT4(RTASN1TMPL_INT_NAME,_PC_XTAG_,a_Name,_Clone), \ RT_CONCAT4(RTASN1TMPL_INT_NAME,_PC_XTAG_,a_Name,_Compare), \ RT_CONCAT4(RTASN1TMPL_INT_NAME,_PC_XTAG_,a_Name,_CheckSanity), \ /*.pfnEncodePrep */ NULL, \ /*.pfnEncodeWrite */ NULL \ } # define RTASN1TMPL_END_PCHOICE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_SEQ_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_SET_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SEMICOLON_DUMMY() #elif RTASN1TMPL_PASS == RTASN1TMPL_PASS_VTABLE /* * * Internal header file. * */ # ifndef RTASN1TMPL_VTABLE_FN_ENCODE_PREP # define RTASN1TMPL_VTABLE_FN_ENCODE_PREP NULL # endif # ifndef RTASN1TMPL_VTABLE_FN_ENCODE_WRITE # define RTASN1TMPL_VTABLE_FN_ENCODE_WRITE NULL # endif # define RTASN1TMPL_BEGIN_COMMON(a_uDefaultTag, a_fDefaultClass) \ DECL_HIDDEN_CONST(RTASN1COREVTABLE const) RT_CONCAT3(g_,RTASN1TMPL_INT_NAME,_Vtable) = \ { \ /* When the Asn1Core is at the start of the structure, we can reuse the _Delete and _Enum APIs here. */ \ /* .pszName = */ RT_XSTR(RTASN1TMPL_EXT_NAME), \ /* .cb = */ sizeof(RTASN1TMPL_TYPE), \ /* .uDefaultTag = */ a_uDefaultTag, \ /* .fDefaultClass = */ a_fDefaultClass, \ /* .uReserved = */ 0, \ (PFNRTASN1COREVTDTOR)RT_CONCAT(RTASN1TMPL_EXT_NAME,_Delete), \ (PFNRTASN1COREVTENUM)RT_CONCAT(RTASN1TMPL_EXT_NAME,_Enum), \ (PFNRTASN1COREVTCLONE)RT_CONCAT(RTASN1TMPL_EXT_NAME,_Clone), \ (PFNRTASN1COREVTCOMPARE)RT_CONCAT(RTASN1TMPL_EXT_NAME,_Compare), \ (PFNRTASN1COREVTCHECKSANITY)RT_CONCAT(RTASN1TMPL_EXT_NAME,_CheckSanity), \ RTASN1TMPL_VTABLE_FN_ENCODE_PREP, \ RTASN1TMPL_VTABLE_FN_ENCODE_WRITE \ } # define RTASN1TMPL_BEGIN_SEQCORE() \ AssertCompileMemberOffset(RTASN1TMPL_TYPE, SeqCore, 0); \ RTASN1TMPL_BEGIN_COMMON(ASN1_TAG_SEQUENCE, ASN1_TAGCLASS_UNIVERSAL | ASN1_TAGFLAG_CONSTRUCTED) # define RTASN1TMPL_BEGIN_SETCORE() \ AssertCompileMemberOffset(RTASN1TMPL_TYPE, SetCore, 0); \ RTASN1TMPL_BEGIN_COMMON(ASN1_TAG_SET, ASN1_TAGCLASS_UNIVERSAL | ASN1_TAGFLAG_CONSTRUCTED) # define RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, a_Constraints) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_MEMBER_DYN_BEGIN(a_enmType, a_enmMembNm, a_Allocation) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_MEMBER_DYN_END(a_enmType, a_enmMembNm, a_Allocation) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_END_SEQCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_END_SETCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_PCHOICE() \ AssertCompileMemberOffset(RTASN1TMPL_TYPE, Dummy, 0); \ RTASN1TMPL_BEGIN_COMMON(UINT8_MAX, UINT8_MAX) # define RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, a_fClue, a_Constraints) \ RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_PCHOICE_XTAG_EX(a_uTag, a_enmChoice, a_PtrTnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_Constraints) \ RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_END_PCHOICE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_SEQ_OF(a_ItemType, a_ItemApi) \ AssertCompileMemberOffset(RTASN1TMPL_TYPE, SeqCore, 0); \ RTASN1TMPL_BEGIN_COMMON(ASN1_TAG_SEQUENCE, ASN1_TAGCLASS_UNIVERSAL | ASN1_TAGFLAG_CONSTRUCTED) # define RTASN1TMPL_SET_OF(a_ItemType, a_ItemApi) \ AssertCompileMemberOffset(RTASN1TMPL_TYPE, SetCore, 0); \ RTASN1TMPL_BEGIN_COMMON(ASN1_TAG_SET, ASN1_TAGCLASS_UNIVERSAL | ASN1_TAGFLAG_CONSTRUCTED) #elif RTASN1TMPL_PASS == RTASN1TMPL_PASS_INIT /* * * Initialization to standard / default values. * */ # define RTASN1TMPL_BEGIN_COMMON() \ RTASN1TMPL_DECL(int) RT_CONCAT(RTASN1TMPL_EXT_NAME,_Init)(RT_CONCAT(P,RTASN1TMPL_TYPE) pThis, PCRTASN1ALLOCATORVTABLE pAllocator) \ { \ RT_NOREF_PV(pAllocator); \ RT_ZERO(*pThis) # define RTASN1TMPL_END_COMMON() \ return rc; \ } RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_SEQCORE() \ RTASN1TMPL_BEGIN_COMMON(); \ int rc = RTAsn1SequenceCore_Init(&pThis->SeqCore, &RT_CONCAT3(g_,RTASN1TMPL_INT_NAME,_Vtable)) # define RTASN1TMPL_BEGIN_SETCORE() \ RTASN1TMPL_BEGIN_COMMON(); \ int rc = RTAsn1SetCore_Init(&pThis->SetCore, &RT_CONCAT3(g_,RTASN1TMPL_INT_NAME,_Vtable)) # define RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, a_Constraints) \ if (RT_SUCCESS(rc)) \ rc = RT_CONCAT(a_Api,_Init)(&pThis->a_Name, pAllocator) # define RTASN1TMPL_MEMBER_DYN_BEGIN(a_enmType, a_enmMembNm, a_Allocation) \ RTAsn1MemInitAllocation(&pThis->Allocation, pAllocator); \ pThis->a_enmMembNm = RT_CONCAT(a_enmType,_NOT_PRESENT) # define RTASN1TMPL_MEMBER_DYN_COMMON(a_UnionNm, a_PtrName, a_Type, a_Api, a_Allocation, a_enmMembNm, a_enmValue, a_IfStmt) \ do { } while (0) # define RTASN1TMPL_MEMBER_DYN_END(a_enmType, a_enmMembNm, a_Allocation) do { } while (0) # define RTASN1TMPL_MEMBER_DEF_ITAG_EX(a_Name, a_Type, a_Api, a_uTag, a_fClue, a_DefVal, a_Constraints) \ if (RT_SUCCESS(rc)) \ { \ rc = RT_CONCAT(a_Api,_InitDefault)(&pThis->a_Name, a_DefVal, pAllocator); \ if (RT_SUCCESS(rc)) \ rc = RTAsn1Core_SetTagAndFlags(RT_CONCAT(a_Api,_GetAsn1Core)(&pThis->a_Name), \ a_uTag, RTASN1TMPL_ITAG_F_EXPAND(a_fClue)); \ } # define RTASN1TMPL_MEMBER_OPT_EX(a_Name, a_Type, a_Api, a_Constraints) do { } while (0) /* All optional members are left as not-present. */ # define RTASN1TMPL_END_SEQCORE() \ if (RT_FAILURE(rc)) \ RT_CONCAT(RTASN1TMPL_EXT_NAME,_Delete)(pThis); \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_END_SETCORE() RTASN1TMPL_END_SEQCORE() /* No choice, just an empty, non-present structure. */ # define RTASN1TMPL_BEGIN_PCHOICE() RTASN1TMPL_BEGIN_COMMON(); int rc = VINF_SUCCESS # define RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, a_fClue, a_Constraints) \ do { } while (0) # define RTASN1TMPL_PCHOICE_XTAG_EX(a_uTag, a_enmChoice, a_PtrTnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_Constraints) \ do { } while (0) # define RTASN1TMPL_END_PCHOICE() RTASN1TMPL_END_COMMON() # define RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi, a_OfApi, a_OfMember) \ RTASN1TMPL_BEGIN_COMMON(); \ RTAsn1MemInitArrayAllocation(&pThis->Allocation, pAllocator, sizeof(a_ItemType)); \ int rc = RT_CONCAT(a_OfApi,_Init)(&pThis->a_OfMember, &RT_CONCAT3(g_,RTASN1TMPL_INT_NAME,_Vtable)); \ if (RT_FAILURE(rc)) \ RT_ZERO(*pThis); \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_SEQ_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi, RTAsn1SeqOfCore, SeqCore) # define RTASN1TMPL_SET_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi, RTAsn1SetOfCore, SetCore) #elif RTASN1TMPL_PASS == RTASN1TMPL_PASS_DECODE /* * * Decode ASN.1. * */ # define RTASN1TMPL_BEGIN_COMMON() \ RTASN1TMPL_DECL(int) RT_CONCAT(RTASN1TMPL_EXT_NAME,_DecodeAsn1)(PRTASN1CURSOR pCursor, uint32_t fFlags, \ RT_CONCAT(P,RTASN1TMPL_TYPE) pThis, const char *pszErrorTag) \ { \ RT_ZERO(*pThis); # define RTASN1TMPL_END_COMMON() \ return rc; \ } RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_SEQCORE() \ RTASN1TMPL_BEGIN_COMMON(); \ RTASN1CURSOR ThisCursor; \ int rc = RTAsn1CursorGetSequenceCursor(pCursor, fFlags, &pThis->SeqCore, &ThisCursor, pszErrorTag); \ if (RT_FAILURE(rc)) \ return rc; \ pCursor = &ThisCursor; \ pThis->SeqCore.Asn1Core.pOps = &RT_CONCAT3(g_,RTASN1TMPL_INT_NAME,_Vtable) # define RTASN1TMPL_BEGIN_SETCORE() \ RTASN1TMPL_BEGIN_COMMON(); \ RTASN1CURSOR ThisCursor; \ int rc = RTAsn1CursorGetSetCursor(pCursor, fFlags, &pThis->SetCore, &ThisCursor, pszErrorTag); \ if (RT_FAILURE(rc)) \ return rc; \ pCursor = &ThisCursor; \ pThis->SetCore.Asn1Core.pOps = &RT_CONCAT3(g_,RTASN1TMPL_INT_NAME,_Vtable) # define RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, a_Constraints) \ if (RT_SUCCESS(rc)) \ rc = RT_CONCAT(a_Api,_DecodeAsn1)(pCursor, 0, &pThis->a_Name, #a_Name) # define RTASN1TMPL_MEMBER_DYN_BEGIN(a_enmType, a_enmMembNm, a_Allocation) \ if (RT_SUCCESS(rc)) \ { \ int rc2; /* not initialized! */ \ RTAsn1CursorInitAllocation(pCursor, &pThis->a_Allocation); \ pThis->a_enmMembNm = RT_CONCAT(a_enmType, _INVALID); \ if (false) do { /*nothing*/ } while (0) # define RTASN1TMPL_MEMBER_DYN_COMMON(a_UnionNm, a_PtrName, a_Type, a_Api, a_Allocation, a_enmMembNm, a_enmValue, a_IfStmt) \ else a_IfStmt \ do { \ rc2 = RTAsn1MemAllocZ(&pThis->a_Allocation, (void **)&pThis->a_UnionNm.a_PtrName, \ sizeof(*pThis->a_UnionNm.a_PtrName)); \ if (RT_SUCCESS(rc2)) \ { \ pThis->a_enmMembNm = a_enmValue; \ rc2 = RT_CONCAT(a_Api,_DecodeAsn1)(pCursor, 0, pThis->a_UnionNm.a_PtrName, #a_UnionNm "." #a_PtrName); \ } \ } while (0) # define RTASN1TMPL_MEMBER_DYN_END(a_enmType, a_enmMembNm, a_Allocation) \ rc = rc2; /* Should trigger warning if a _DEFAULT is missing. */ \ } # define RTASN1TMPL_MEMBER_OPT_EX(a_Name, a_Type, a_Api, a_Constraints) \ Error_Missing_Specific_Macro_In_Decode_Pass() # define RTASN1TMPL_MEMBER_DEF_ITAG_EX(a_Name, a_Type, a_Api, a_uTag, a_fClue, a_DefVal, a_Constraints) \ if (RT_SUCCESS(rc)) \ { \ if (RTAsn1CursorIsNextEx(pCursor, a_uTag, RTASN1TMPL_ITAG_F_EXPAND(a_fClue))) \ rc = RT_CONCAT(a_Api,_DecodeAsn1)(pCursor, 0, &pThis->a_Name, #a_Name); \ else \ rc = RT_CONCAT(a_Api,_InitDefault)(&pThis->a_Name, a_DefVal, pCursor->pPrimary->pAllocator); \ if (RT_SUCCESS(rc)) \ rc = RTAsn1Core_SetTagAndFlags(RT_CONCAT(a_Api,_GetAsn1Core)(&pThis->a_Name), \ a_uTag, RTASN1TMPL_ITAG_F_EXPAND(a_fClue)); \ } do {} while (0) # define RTASN1TMPL_MEMBER_OPT_UTF8_STRING_EX(a_Name, a_Constraints) \ if (RT_SUCCESS(rc) && RTAsn1CursorIsNextEx(pCursor, ASN1_TAG_UTF8_STRING, ASN1_TAGCLASS_CONTEXT | ASN1_TAGFLAG_PRIMITIVE)) \ rc = RTAsn1CursorGetUtf8String(pCursor, 0, &pThis->a_Name, #a_Name) # define RTASN1TMPL_MEMBER_OPT_ITAG_EX(a_Name, a_Type, a_Api, a_uTag, a_fClue, a_Constraints) \ if (RT_SUCCESS(rc) && RTAsn1CursorIsNextEx(pCursor, a_uTag, RTASN1TMPL_ITAG_F_EXPAND(a_fClue)) /** @todo || CER */) \ rc = RT_CONCAT(a_Api,_DecodeAsn1)(pCursor, RTASN1CURSOR_GET_F_IMPLICIT, &pThis->a_Name, #a_Name) # define RTASN1TMPL_MEMBER_OPT_ITAG_BITSTRING(a_Name, a_cMaxBits, a_uTag) \ if (RT_SUCCESS(rc) && RTAsn1CursorIsNextEx(pCursor, a_uTag, ASN1_TAGCLASS_CONTEXT | ASN1_TAGFLAG_CONSTRUCTED)) \ rc = RTAsn1CursorGetBitStringEx(pCursor, RTASN1CURSOR_GET_F_IMPLICIT, a_cMaxBits, &pThis->a_Name, #a_Name) # define RTASN1TMPL_MEMBER_OPT_XTAG_EX(a_TnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_uTag, a_Constraints) \ if (RT_SUCCESS(rc) && RTAsn1CursorIsNextEx(pCursor, a_uTag, ASN1_TAGCLASS_CONTEXT | ASN1_TAGFLAG_CONSTRUCTED)) \ { \ RTASN1CURSOR CtxCursor; \ rc = RT_CONCAT3(RTAsn1CursorGetContextTag,a_uTag,Cursor)(pCursor, 0, \ &RT_CONCAT5(g_,RTASN1TMPL_INT_NAME,_XTAG_,a_Name,_Vtable), \ &pThis->a_TnNm.a_CtxTagN, &CtxCursor, #a_TnNm); \ if (RT_SUCCESS(rc)) \ { \ rc = RT_CONCAT(a_Api,_DecodeAsn1)(&CtxCursor, 0, &pThis->a_TnNm.a_Name, #a_Name); \ if (RT_SUCCESS(rc)) \ rc = RTAsn1CursorCheckEnd(&CtxCursor); \ } \ } do { } while (0) # define RTASN1TMPL_MEMBER_OPT_ANY(a_Name, a_Type, a_Api) \ if (RT_SUCCESS(rc) && pCursor->cbLeft > 0) \ RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, RT_NOTHING) # define RTASN1TMPL_END_SEQCORE() \ if (RT_SUCCESS(rc)) \ rc = RTAsn1CursorCheckSeqEnd(&ThisCursor, &pThis->SeqCore); \ if (RT_SUCCESS(rc)) \ return VINF_SUCCESS; \ RT_CONCAT(RTASN1TMPL_EXT_NAME,_Delete)(pThis); \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_END_SETCORE() \ if (RT_SUCCESS(rc)) \ rc = RTAsn1CursorCheckSetEnd(&ThisCursor, &pThis->SetCore); \ if (RT_SUCCESS(rc)) \ return VINF_SUCCESS; \ RT_CONCAT(RTASN1TMPL_EXT_NAME,_Delete)(pThis); \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_BEGIN_PCHOICE() \ RTASN1TMPL_BEGIN_COMMON(); \ RT_NOREF_PV(fFlags); \ RTAsn1Dummy_InitEx(&pThis->Dummy); \ pThis->Dummy.Asn1Core.pOps = &RT_CONCAT3(g_,RTASN1TMPL_INT_NAME,_Vtable); \ RTAsn1CursorInitAllocation(pCursor, &pThis->Allocation); \ RTASN1CORE Asn1Peek; \ int rc = RTAsn1CursorPeek(pCursor, &Asn1Peek); \ if (RT_SUCCESS(rc)) \ { \ if (false) do {} while (0) # define RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, a_fClue, a_Constraints) \ else if ( Asn1Peek.uTag == (a_uTag) \ && (Asn1Peek.fClass == RTASN1TMPL_ITAG_F_EXPAND(a_fClue) /** @todo || CER */ ) ) \ do { \ pThis->enmChoice = a_enmChoice; \ rc = RTAsn1MemAllocZ(&pThis->Allocation, (void **)&pThis->a_PtrName, sizeof(*pThis->a_PtrName)); \ if (RT_SUCCESS(rc)) \ rc = RT_CONCAT(a_Api,_DecodeAsn1)(pCursor, RTASN1CURSOR_GET_F_IMPLICIT, pThis->a_PtrName, #a_PtrName); \ } while (0) # define RTASN1TMPL_PCHOICE_XTAG_EX(a_uTag, a_enmChoice, a_PtrTnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_Constraints) \ else if (Asn1Peek.uTag == (a_uTag) && Asn1Peek.fClass == (ASN1_TAGCLASS_CONTEXT | ASN1_TAGFLAG_CONSTRUCTED)) \ do { \ pThis->enmChoice = a_enmChoice; \ rc = RTAsn1MemAllocZ(&pThis->Allocation, (void **)&pThis->a_PtrTnNm, sizeof(*pThis->a_PtrTnNm)); \ if (RT_SUCCESS(rc)) \ { \ RTASN1CURSOR CtxCursor; \ rc = RT_CONCAT3(RTAsn1CursorGetContextTag,a_uTag,Cursor)(pCursor, 0, \ &RT_CONCAT5(g_,RTASN1TMPL_INT_NAME,_PCHOICE_XTAG_,a_Name,_Vtable), \ &pThis->a_PtrTnNm->a_CtxTagN, &CtxCursor, "T" #a_uTag); \ if (RT_SUCCESS(rc)) \ rc = RT_CONCAT(a_Api,_DecodeAsn1)(&CtxCursor, RTASN1CURSOR_GET_F_IMPLICIT, \ &pThis->a_PtrTnNm->a_Name, #a_Name); \ if (RT_SUCCESS(rc)) \ rc = RTAsn1CursorCheckEnd(&CtxCursor); \ } \ } while (0) #define RTASN1TMPL_END_PCHOICE() \ else \ rc = RTAsn1CursorSetInfo(pCursor, VERR_GENERAL_FAILURE, "%s: Unknown choice: tag=%#x fClass=%#x", \ pszErrorTag, Asn1Peek.uTag, Asn1Peek.fClass); \ if (RT_SUCCESS(rc)) \ return VINF_SUCCESS; \ } \ RT_CONCAT(RTASN1TMPL_EXT_NAME,_Delete)(pThis); \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi, a_OfApi, a_OfMember, a_fnGetCursor) \ RTASN1TMPL_BEGIN_COMMON(); \ RTASN1CURSOR ThisCursor; \ int rc = a_fnGetCursor(pCursor, fFlags, &pThis->a_OfMember, &ThisCursor, pszErrorTag); \ if (RT_SUCCESS(rc)) \ { \ pCursor = &ThisCursor; \ pThis->a_OfMember.Asn1Core.pOps = &RT_CONCAT3(g_,RTASN1TMPL_INT_NAME,_Vtable); \ RTAsn1CursorInitArrayAllocation(pCursor, &pThis->Allocation, sizeof(a_ItemType)); \ \ uint32_t i = 0; \ while ( pCursor->cbLeft > 0 \ && RT_SUCCESS(rc)) \ { \ rc = RTAsn1MemResizeArray(&pThis->Allocation, (void ***)&pThis->papItems, i, i + 1); \ if (RT_SUCCESS(rc)) \ { \ rc = RT_CONCAT(a_ItemApi,_DecodeAsn1)(pCursor, 0, pThis->papItems[i], "papItems[#]"); \ if (RT_SUCCESS(rc)) \ { \ i++; \ pThis->cItems = i; \ continue; \ } \ } \ break; \ } \ if (RT_SUCCESS(rc)) \ { \ rc = RTAsn1CursorCheckEnd(pCursor); \ if (RT_SUCCESS(rc)) \ return VINF_SUCCESS; \ } \ RT_CONCAT(RTASN1TMPL_EXT_NAME,_Delete)(pThis); \ } \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_SEQ_OF(a_ItemType, a_ItemApi) \ RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi, RTAsn1SeqOfCore, SeqCore, RTAsn1CursorGetSequenceCursor) # define RTASN1TMPL_SET_OF(a_ItemType, a_ItemApi) \ RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi, RTAsn1SetOfCore, SetCore, RTAsn1CursorGetSetCursor) # define RTASN1TMPL_EXEC_DECODE(a_Expr) if (RT_SUCCESS(rc)) { a_Expr; } #elif RTASN1TMPL_PASS == RTASN1TMPL_PASS_ENUM /* * * Enumeration. * */ # define RTASN1TMPL_BEGIN_COMMON() \ RTASN1TMPL_DECL(int) RT_CONCAT(RTASN1TMPL_EXT_NAME,_Enum)(RT_CONCAT(P,RTASN1TMPL_TYPE) pThis, \ PFNRTASN1ENUMCALLBACK pfnCallback, \ uint32_t uDepth, void *pvUser) \ { \ if (!RT_CONCAT(RTASN1TMPL_EXT_NAME,_IsPresent)(pThis)) \ return VINF_SUCCESS; \ uDepth++; \ int rc = VINF_SUCCESS # define RTASN1TMPL_END_COMMON() \ return rc; \ } RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_SEQCORE() RTASN1TMPL_BEGIN_COMMON() # define RTASN1TMPL_BEGIN_SETCORE() RTASN1TMPL_BEGIN_COMMON() # define RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, a_Constraints) \ if (rc == VINF_SUCCESS) \ rc = pfnCallback(RT_CONCAT(a_Api,_GetAsn1Core)(&pThis->a_Name), #a_Name, uDepth, pvUser) # define RTASN1TMPL_MEMBER_DYN_BEGIN(a_enmType, a_enmMembNm, a_Allocation) \ if (rc == VINF_SUCCESS) \ switch (pThis->a_enmMembNm) \ { \ default: rc = VERR_INTERNAL_ERROR_3; break # define RTASN1TMPL_MEMBER_DYN_COMMON(a_UnionNm, a_PtrName, a_Type, a_Api, a_Allocation, a_enmMembNm, a_enmValue, a_IfStmt) \ case a_enmValue: \ rc = pfnCallback(RT_CONCAT(a_Api,_GetAsn1Core)(pThis->a_UnionNm.a_PtrName), #a_UnionNm "." #a_PtrName, \ uDepth, pvUser); \ break # define RTASN1TMPL_MEMBER_DYN_END(a_enmType, a_enmMembNm, a_Allocation) \ case RT_CONCAT(a_enmType,_NOT_PRESENT): break; \ } # define RTASN1TMPL_MEMBER_OPT_EX(a_Name, a_Type, a_Api, a_Constraints) \ if (rc == VINF_SUCCESS && RT_CONCAT(a_Api,_IsPresent)(&pThis->a_Name)) \ rc = pfnCallback(RT_CONCAT(a_Api,_GetAsn1Core)(&pThis->a_Name), #a_Name, uDepth, pvUser) # define RTASN1TMPL_MEMBER_OPT_XTAG_EX(a_TnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_uTag, a_Constraints) \ if (rc == VINF_SUCCESS && RTASN1CORE_IS_PRESENT(&pThis->a_TnNm.a_CtxTagN.Asn1Core)) \ { \ rc = pfnCallback(&pThis->a_TnNm.a_CtxTagN.Asn1Core, #a_Name, uDepth, pvUser); \ } do {} while (0) # define RTASN1TMPL_END_SEQCORE() RTASN1TMPL_END_COMMON() # define RTASN1TMPL_END_SETCORE() RTASN1TMPL_END_COMMON() # define RTASN1TMPL_BEGIN_PCHOICE() \ RTASN1TMPL_BEGIN_COMMON(); \ switch (pThis->enmChoice) \ { \ default: rc = VERR_INTERNAL_ERROR_3; break # define RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, a_fClue, a_Constraints) \ case a_enmChoice: rc = pfnCallback(RT_CONCAT(a_Api,_GetAsn1Core)(pThis->a_PtrName), #a_PtrName, uDepth, pvUser); break # define RTASN1TMPL_PCHOICE_XTAG_EX(a_uTag, a_enmChoice, a_PtrTnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_Constraints) \ case a_enmChoice: rc = pfnCallback(&pThis->a_PtrTnNm->a_CtxTagN.Asn1Core, "T" #a_uTag "." #a_CtxTagN, uDepth, pvUser); break #define RTASN1TMPL_END_PCHOICE() \ } \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi) \ RTASN1TMPL_BEGIN_COMMON(); \ for (uint32_t i = 0; i < pThis->cItems && rc == VINF_SUCCESS; i++) \ rc = pfnCallback(RT_CONCAT(a_ItemApi,_GetAsn1Core)(pThis->papItems[i]), "papItems[#]", uDepth, pvUser); \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_SEQ_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi) # define RTASN1TMPL_SET_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi) #elif RTASN1TMPL_PASS == RTASN1TMPL_PASS_CLONE /* * * Clone another instance of the type. * */ # define RTASN1TMPL_BEGIN_COMMON() \ RTASN1TMPL_DECL(int) RT_CONCAT(RTASN1TMPL_EXT_NAME,_Clone)(RT_CONCAT(P,RTASN1TMPL_TYPE) pThis, \ RT_CONCAT(PC,RTASN1TMPL_TYPE) pSrc, \ PCRTASN1ALLOCATORVTABLE pAllocator) \ { \ RT_ZERO(*pThis); \ if (!RT_CONCAT(RTASN1TMPL_EXT_NAME,_IsPresent)(pSrc)) \ return VINF_SUCCESS; \ # define RTASN1TMPL_END_COMMON() \ return rc; \ } RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_SEQCORE() \ RTASN1TMPL_BEGIN_COMMON(); \ int rc = RTAsn1SequenceCore_Clone(&pThis->SeqCore, &RT_CONCAT3(g_, RTASN1TMPL_INT_NAME, _Vtable), &pSrc->SeqCore) # define RTASN1TMPL_BEGIN_SETCORE() \ RTASN1TMPL_BEGIN_COMMON(); \ int rc = RTAsn1SetCore_Clone(&pThis->SetCore, &RT_CONCAT3(g_, RTASN1TMPL_INT_NAME, _Vtable), &pSrc->SetCore) # define RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, a_Constraints) \ if (RT_SUCCESS(rc)) \ rc = RT_CONCAT(a_Api,_Clone)(&pThis->a_Name, &pSrc->a_Name, pAllocator); \ # define RTASN1TMPL_MEMBER_DYN_BEGIN(a_enmType, a_enmMembNm, a_Allocation) \ if (RT_SUCCESS(rc)) \ { \ RTAsn1MemInitAllocation(&pThis->Allocation, pAllocator); \ pThis->a_enmMembNm = pSrc->a_enmMembNm; \ switch (pSrc->a_enmMembNm) \ { \ default: rc = VERR_INTERNAL_ERROR_3; break # define RTASN1TMPL_MEMBER_DYN_COMMON(a_UnionNm, a_PtrName, a_Type, a_Api, a_Allocation, a_enmMembNm, a_enmValue, a_IfStmt) \ case a_enmValue: \ rc = RTAsn1MemAllocZ(&pThis->a_Allocation, (void **)&pThis->a_UnionNm.a_PtrName, \ sizeof(*pThis->a_UnionNm.a_PtrName)); \ if (RT_SUCCESS(rc)) \ rc = RT_CONCAT(a_Api,_Clone)(pThis->a_UnionNm.a_PtrName, pSrc->a_UnionNm.a_PtrName, pAllocator); \ break # define RTASN1TMPL_MEMBER_DYN_END(a_enmType, a_enmMembNm, a_Allocation) \ case RT_CONCAT(a_enmType,_NOT_PRESENT): break; \ } \ } /* Optional members and members with defaults are the same as a normal member when cloning. */ # define RTASN1TMPL_MEMBER_OPT_UTF8_STRING_EX(a_Name, a_Constraints) \ RTASN1TMPL_MEMBER_OPT_EX(a_Name, RTASN1STRING, RTAsn1Utf8String, a_Constraints RT_NOTHING) # define RTASN1TMPL_MEMBER_OPT_XTAG_EX(a_TnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_uTag, a_Constraints) \ if (RTASN1CORE_IS_PRESENT(&pSrc->a_TnNm.a_CtxTagN.Asn1Core) && RT_SUCCESS(rc)) \ { \ rc = RT_CONCAT3(RTAsn1ContextTag,a_uTag,_Clone)(&pThis->a_TnNm.a_CtxTagN, &pSrc->a_TnNm.a_CtxTagN); \ if (RT_SUCCESS(rc)) \ rc = RT_CONCAT(a_Api,_Clone)(&pThis->a_TnNm.a_Name, &pSrc->a_TnNm.a_Name, pAllocator); \ } do { } while (0) # define RTASN1TMPL_END_SEQCORE() \ if (RT_FAILURE(rc)) \ RT_CONCAT(RTASN1TMPL_EXT_NAME,_Delete)(pThis); \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_END_SETCORE() RTASN1TMPL_END_SEQCORE() # define RTASN1TMPL_BEGIN_PCHOICE() \ RTASN1TMPL_BEGIN_COMMON(); \ RTAsn1Dummy_InitEx(&pThis->Dummy); \ pThis->Dummy.Asn1Core.pOps = &RT_CONCAT3(g_,RTASN1TMPL_INT_NAME,_Vtable); \ RTAsn1MemInitAllocation(&pThis->Allocation, pAllocator); \ int rc; \ pThis->enmChoice = pSrc->enmChoice; \ switch (pSrc->enmChoice) \ { \ default: rc = VERR_INTERNAL_ERROR_3; break # define RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, a_fClue, a_Constraints) \ case a_enmChoice: \ rc = RTAsn1MemAllocZ(&pThis->Allocation, (void **)&pThis->a_PtrName, sizeof(*pThis->a_PtrName)); \ if (RT_SUCCESS(rc)) \ rc = RT_CONCAT(a_Api,_Clone)(pThis->a_PtrName, pSrc->a_PtrName, pAllocator); \ break # define RTASN1TMPL_PCHOICE_XTAG_EX(a_uTag, a_enmChoice, a_PtrTnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_Constraints) \ case a_enmChoice: /* A bit of presence paranoia here, but better safe than sorry... */ \ rc = RTAsn1MemAllocZ(&pThis->Allocation, (void **)&pThis->a_PtrTnNm, sizeof(*pThis->a_PtrTnNm)); \ if (RT_SUCCESS(rc) && RTASN1CORE_IS_PRESENT(&pSrc->a_PtrTnNm->a_CtxTagN.Asn1Core)) \ { \ RT_CONCAT3(RTAsn1ContextTag,a_uTag,_Clone)(&pThis->a_PtrTnNm->a_CtxTagN, &pSrc->a_PtrTnNm->a_CtxTagN); \ rc = RT_CONCAT(a_Api,_Clone)(&pThis->a_PtrTnNm->a_Name, &pSrc->a_PtrTnNm->a_Name, pAllocator); \ } \ break #define RTASN1TMPL_END_PCHOICE() \ } \ if (RT_FAILURE(rc)) \ RT_CONCAT(RTASN1TMPL_EXT_NAME,_Delete)(pThis); \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi, a_OfApi, a_OfMember) \ RTASN1TMPL_BEGIN_COMMON(); \ int rc = RT_CONCAT(a_OfApi,_Clone)(&pThis->a_OfMember, &RT_CONCAT3(g_,RTASN1TMPL_INT_NAME,_Vtable), &pSrc->a_OfMember); \ if (RT_SUCCESS(rc)) \ { \ RTAsn1MemInitArrayAllocation(&pThis->Allocation, pAllocator, sizeof(a_ItemType)); \ uint32_t const cItems = pSrc->cItems; \ if (cItems > 0) \ { \ rc = RTAsn1MemResizeArray(&pThis->Allocation, (void ***)&pThis->papItems, 0, cItems); \ if (RT_SUCCESS(rc)) \ { \ uint32_t i = 0; \ while (i < cItems) \ { \ rc = RT_CONCAT(a_ItemApi,_Clone)(pThis->papItems[i], pSrc->papItems[i], pAllocator); \ if (RT_SUCCESS(rc)) \ pThis->cItems = ++i; \ else \ { \ pThis->cItems = i; \ RT_CONCAT(RTASN1TMPL_EXT_NAME,_Delete)(pThis); \ return rc; \ } \ } \ } \ else \ RT_ZERO(*pThis); \ } \ } \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_SEQ_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi, RTAsn1SeqOfCore, SeqCore) # define RTASN1TMPL_SET_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi, RTAsn1SetOfCore, SetCore) # define RTASN1TMPL_EXEC_CLONE(a_Expr) if (RT_SUCCESS(rc)) { a_Expr; } #elif RTASN1TMPL_PASS == RTASN1TMPL_PASS_SETTERS_1 /* * * Member setter helpers. * */ # define RTASN1TMPL_BEGIN_SEQCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_SETCORE() RTASN1TMPL_SEMICOLON_DUMMY() #if 1 /** @todo later */ # define RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, a_Constraints) RTASN1TMPL_SEMICOLON_DUMMY() #else # define RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, a_Constraints) \ RTDECL(int) RT_CONCAT3(RTASN1TMPL_EXT_NAME,_Set,a_Name)(RTASN1TMPL_TYPE *pThis, a_Type const *pValue, \ PCRTASN1ALLOCATORVTABLE pAllocator) \ { \ if (RT_CONCAT(a_Api,_IsPresent)(&pThis->a_Name)) \ RT_CONCAT(a_Api,_Delete)(&pThis->a_Name); \ return RT_CONCAT(a_Api,_Clone)(&pThis->a_Name, pValue, pAllocator, true /* fResetImplicit */); \ } RTASN1TMPL_SEMICOLON_DUMMY() #endif # define RTASN1TMPL_MEMBER_DYN_BEGIN(a_enmType, a_enmMembNm, a_Allocation) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_MEMBER_DYN_END(a_enmType, a_enmMembNm, a_Allocation) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_END_SEQCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_END_SETCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_PCHOICE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, a_fClue, a_Constraints) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_PCHOICE_XTAG_EX(a_uTag, a_enmChoice, a_PtrTnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_Constraints) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_END_PCHOICE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_SEQ_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_SET_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SEMICOLON_DUMMY() #elif RTASN1TMPL_PASS == RTASN1TMPL_PASS_SETTERS_2 /* * * Member setters. * */ # define RTASN1TMPL_BEGIN_SEQCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_SETCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, a_Constraints) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_MEMBER_DYN_BEGIN(a_enmType, a_enmMembNm, a_Allocation) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_MEMBER_DYN_END(a_enmType, a_enmMembNm, a_Allocation) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_END_SEQCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_END_SETCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_PCHOICE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, a_fClue, a_Constraints) \ RTASN1TMPL_DECL(int) RT_CONCAT3(RTASN1TMPL_EXT_NAME,_Set,a_Name)(RT_CONCAT(P,RTASN1TMPL_TYPE) pThis, RT_CONCAT(PC,a_Type) pSrc,\ PCRTASN1ALLOCATORVTABLE pAllocator) \ { \ AssertPtr(pSrc); AssertPtr(pThis); \ RT_CONCAT(RTASN1TMPL_EXT_NAME,_Delete)(pThis); /* See _Init. */ \ RTAsn1Dummy_InitEx(&pThis->Dummy); \ pThis->Dummy.Asn1Core.pOps = &RT_CONCAT3(g_,RTASN1TMPL_INT_NAME,_Vtable); \ RTAsn1MemInitAllocation(&pThis->Allocation, pAllocator); \ pThis->enmChoice = a_enmChoice; \ int rc = RTAsn1MemAllocZ(&pThis->Allocation, (void **)&pThis->a_PtrName, sizeof(*pThis->a_PtrName)); \ if (RT_SUCCESS(rc)) \ { \ rc = RT_CONCAT(a_Api,_Clone)(pThis->a_PtrName, pSrc, pAllocator); \ if (RT_SUCCESS(rc)) \ { \ RTAsn1Core_ResetImplict(RT_CONCAT(a_Api,_GetAsn1Core)(pThis->a_PtrName)); \ rc = RTAsn1Core_SetTagAndFlags(RT_CONCAT(a_Api,_GetAsn1Core)(pThis->a_PtrName), \ a_uTag, RTASN1TMPL_ITAG_F_EXPAND(a_fClue)); \ } \ } \ return rc; \ } RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_PCHOICE_XTAG_EX(a_uTag, a_enmChoice, a_PtrTnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_Constraints) \ RTASN1TMPL_DECL(int) RT_CONCAT3(RTASN1TMPL_EXT_NAME,_Set,a_Name)(RT_CONCAT(P,RTASN1TMPL_TYPE) pThis, RT_CONCAT(PC,a_Type) pSrc,\ PCRTASN1ALLOCATORVTABLE pAllocator) \ { \ AssertPtr(pThis); AssertPtr(pSrc); Assert(RT_CONCAT(a_Api,_IsPresent)(pSrc)); \ RT_CONCAT(RTASN1TMPL_EXT_NAME,_Delete)(pThis); /* See _Init. */ \ RTAsn1Dummy_InitEx(&pThis->Dummy); \ pThis->Dummy.Asn1Core.pOps = &RT_CONCAT3(g_,RTASN1TMPL_INT_NAME,_Vtable); \ RTAsn1MemInitAllocation(&pThis->Allocation, pAllocator); \ pThis->enmChoice = a_enmChoice; \ int rc = RTAsn1MemAllocZ(&pThis->Allocation, (void **)&pThis->a_PtrTnNm, sizeof(*pThis->a_PtrTnNm)); \ if (RT_SUCCESS(rc)) \ { \ rc = RT_CONCAT3(RTAsn1ContextTag,a_uTag,_Init)(&pThis->a_PtrTnNm->a_CtxTagN, \ &RT_CONCAT5(g_,RTASN1TMPL_INT_NAME,_PCHOICE_XTAG_,a_Name,_Vtable), \ pAllocator); \ if (RT_SUCCESS(rc)) \ { \ rc = RT_CONCAT(a_Api,_Clone)(&pThis->a_PtrTnNm->a_Name, pSrc, pAllocator); \ if (RT_SUCCESS(rc)) \ RTAsn1Core_ResetImplict(RT_CONCAT(a_Api,_GetAsn1Core)(&pThis->a_PtrTnNm->a_Name)); \ } \ } \ return rc; \ } RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_END_PCHOICE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_SEQ_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_SET_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SEMICOLON_DUMMY() #elif RTASN1TMPL_PASS == RTASN1TMPL_PASS_ARRAY /* * * Array operations. * */ # define RTASN1TMPL_BEGIN_SEQCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_SETCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, a_Constraints) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_MEMBER_DYN_BEGIN(a_enmType, a_enmMembNm, a_Allocation) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_MEMBER_DYN_END(a_enmType, a_enmMembNm, a_Allocation) RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_END_SEQCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_END_SETCORE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_PCHOICE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, a_fClue, a_Constraints) \ RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_PCHOICE_XTAG_EX(a_uTag, a_enmChoice, a_PtrTnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_Constraints) \ RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_END_PCHOICE() RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi) \ RTASN1TMPL_DECL(int) RT_CONCAT(RTASN1TMPL_EXT_NAME,_Erase)(RT_CONCAT(P,RTASN1TMPL_TYPE) pThis, uint32_t iPosition) \ { \ /* Check and adjust iPosition. */ \ uint32_t const cItems = pThis->cItems; \ if (iPosition < cItems) \ { /* likely */ } \ else \ { \ AssertReturn(iPosition == UINT32_MAX, VERR_OUT_OF_RANGE); \ AssertReturn(cItems > 0, VERR_OUT_OF_RANGE); \ iPosition = cItems - 1; \ } \ \ /* Delete the entry instance. */ \ RT_CONCAT(P, a_ItemType) pErased = pThis->papItems[iPosition]; \ if (RT_CONCAT(a_ItemApi,_IsPresent)(pErased)) \ RT_CONCAT(a_ItemApi,_Delete)(pErased); \ \ /* If not the final entry, shift the other entries up and place the erased on at the end. */ \ if (iPosition < cItems - 1) \ { \ memmove(&pThis->papItems[iPosition], &pThis->papItems[iPosition + 1], (cItems - iPosition - 1) * sizeof(void *)); \ pThis->papItems[cItems - 1] = pErased; \ } \ /* Commit the new array size. */ \ pThis->cItems = cItems - 1; \ \ /* Call the allocator to resize the array (ignore return). */ \ RTAsn1MemResizeArray(&pThis->Allocation, (void ***)&pThis->papItems, cItems - 1, cItems); \ return VINF_SUCCESS; \ } \ \ RTASN1TMPL_DECL(int) RT_CONCAT(RTASN1TMPL_EXT_NAME,_InsertEx)(RT_CONCAT(P,RTASN1TMPL_TYPE) pThis, uint32_t iPosition, \ RT_CONCAT(PC, a_ItemType) pToClone, \ PCRTASN1ALLOCATORVTABLE pAllocator, uint32_t *piActualPos) \ { \ /* Check and adjust iPosition. */ \ uint32_t const cItems = pThis->cItems; \ if (iPosition <= cItems) \ { /* likely */ } \ else \ { \ AssertReturn(iPosition == UINT32_MAX, VERR_OUT_OF_RANGE); \ iPosition = cItems; \ } \ \ /* Ensure we've got space in the array. */ \ int rc = RTAsn1MemResizeArray(&pThis->Allocation, (void ***)&pThis->papItems, cItems, cItems + 1); \ if (RT_SUCCESS(rc)) \ { \ /* Initialize the new entry (which is currently at the end of the array) either with defaults or as a clone. */ \ RT_CONCAT(P,a_ItemType) pInserted = pThis->papItems[cItems]; \ if (RT_CONCAT(a_ItemApi,_IsPresent)(pToClone)) \ rc = RT_CONCAT(a_ItemApi,_Clone)(pInserted, pToClone, pAllocator); \ else \ rc = RT_CONCAT(a_ItemApi,_Init)(pInserted, pAllocator); \ if (RT_SUCCESS(rc)) \ { \ pThis->cItems = cItems + 1; \ \ /* If not inserting at the end of the array, shift existing items out of the way and insert the new as req. */ \ if (iPosition != cItems) \ { \ memmove(&pThis->papItems[iPosition + 1], &pThis->papItems[iPosition], (cItems - iPosition) * sizeof(void *)); \ pThis->papItems[iPosition] = pInserted; \ } \ \ /* Done! */ \ if (piActualPos) \ *piActualPos = iPosition; \ return VINF_SUCCESS; \ } \ RTAsn1MemResizeArray(&pThis->Allocation, (void ***)&pThis->papItems, cItems + 1, cItems); \ } \ return rc; \ } RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_SEQ_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi) # define RTASN1TMPL_SET_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi) #elif RTASN1TMPL_PASS == RTASN1TMPL_PASS_COMPARE /* * * Compare two instances of the type. * */ # define RTASN1TMPL_BEGIN_COMMON() \ RTASN1TMPL_DECL(int) RT_CONCAT(RTASN1TMPL_EXT_NAME,_Compare)(RT_CONCAT(PC,RTASN1TMPL_TYPE) pLeft, \ RT_CONCAT(PC,RTASN1TMPL_TYPE) pRight) \ { \ if (!RT_CONCAT(RTASN1TMPL_EXT_NAME,_IsPresent)(pLeft)) \ return 0 - (int)RT_CONCAT(RTASN1TMPL_EXT_NAME,_IsPresent)(pRight); \ if (!RT_CONCAT(RTASN1TMPL_EXT_NAME,_IsPresent)(pRight)) \ return -1; \ int iDiff = 0 # define RTASN1TMPL_END_COMMON() \ return iDiff; \ } RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_SEQCORE() RTASN1TMPL_BEGIN_COMMON() # define RTASN1TMPL_BEGIN_SETCORE() RTASN1TMPL_BEGIN_COMMON() # define RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, a_Constraints) \ if (!iDiff) \ iDiff = RT_CONCAT(a_Api,_Compare)(&pLeft->a_Name, &pRight->a_Name) # define RTASN1TMPL_MEMBER_DYN_BEGIN(a_enmType, a_enmMembNm, a_Allocation) \ if (!iDiff && pLeft->a_enmMembNm != pRight->a_enmMembNm) \ iDiff = pLeft->a_enmMembNm < pRight->a_enmMembNm ? -1 : 1; \ else if (!iDiff) \ switch (pLeft->a_enmMembNm) \ { \ default: break # define RTASN1TMPL_MEMBER_DYN_COMMON(a_UnionNm, a_PtrName, a_Type, a_Api, a_Allocation, a_enmMembNm, a_enmValue, a_IfStmt) \ case a_enmValue: iDiff = RT_CONCAT(a_Api,_Compare)(pLeft->a_UnionNm.a_PtrName, pRight->a_UnionNm.a_PtrName); break # define RTASN1TMPL_MEMBER_DYN_END(a_enmType, a_enmMembNm, a_Allocation) \ case RT_CONCAT(a_enmType,_NOT_PRESENT): break; \ } # define RTASN1TMPL_MEMBER_OPT_XTAG_EX(a_TnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_uTag, a_Constraints) \ if (!iDiff) \ { \ if (RTASN1CORE_IS_PRESENT(&pLeft->a_TnNm.a_CtxTagN.Asn1Core)) \ { \ if (RTASN1CORE_IS_PRESENT(&pRight->a_TnNm.a_CtxTagN.Asn1Core)) \ iDiff = RT_CONCAT(a_Api,_Compare)(&pLeft->a_TnNm.a_Name, &pRight->a_TnNm.a_Name); \ else \ iDiff = -1; \ } \ else \ iDiff = 0 - (int)RTASN1CORE_IS_PRESENT(&pRight->a_TnNm.a_CtxTagN.Asn1Core); \ } do { } while (0) # define RTASN1TMPL_END_SEQCORE() RTASN1TMPL_END_COMMON() # define RTASN1TMPL_END_SETCORE() RTASN1TMPL_END_COMMON() # define RTASN1TMPL_BEGIN_PCHOICE() \ RTASN1TMPL_BEGIN_COMMON(); \ if (pLeft->enmChoice != pRight->enmChoice) \ return pLeft->enmChoice < pRight->enmChoice ? -1 : 1; \ switch (pLeft->enmChoice) \ { \ default: break # define RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, a_fClue, a_Constraints) \ case a_enmChoice: iDiff = RT_CONCAT(a_Api,_Compare)(pLeft->a_PtrName, pRight->a_PtrName); break # define RTASN1TMPL_PCHOICE_XTAG_EX(a_uTag, a_enmChoice, a_PtrTnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_Constraints) \ case a_enmChoice: iDiff = RT_CONCAT(a_Api,_Compare)(&pLeft->a_PtrTnNm->a_Name, &pRight->a_PtrTnNm->a_Name); break #define RTASN1TMPL_END_PCHOICE() \ } \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi) \ RTASN1TMPL_BEGIN_COMMON(); \ uint32_t cItems = pLeft->cItems; \ if (cItems == pRight->cItems) \ for (uint32_t i = 0; iDiff == 0 && i < cItems; i++) \ iDiff = RT_CONCAT(a_ItemApi,_Compare)(pLeft->papItems[i], pRight->papItems[i]); \ else \ iDiff = cItems < pRight->cItems ? -1 : 1; \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_SEQ_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi) # define RTASN1TMPL_SET_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi) #elif RTASN1TMPL_PASS == RTASN1TMPL_PASS_CHECK_SANITY /* * * Checks the sanity of the type. * */ # ifndef RTASN1TMPL_SANITY_CHECK_EXPR # define RTASN1TMPL_SANITY_CHECK_EXPR() VINF_SUCCESS # endif # define RTASN1TMPL_BEGIN_COMMON() \ RTASN1TMPL_DECL(int) RT_CONCAT(RTASN1TMPL_EXT_NAME,_CheckSanity)(RT_CONCAT(PC,RTASN1TMPL_TYPE) pThis, uint32_t fFlags, \ PRTERRINFO pErrInfo, const char *pszErrorTag) \ { \ if (RT_LIKELY(RT_CONCAT(RTASN1TMPL_EXT_NAME,_IsPresent)(pThis))) \ { /* likely */ } \ else \ return RTErrInfoSetF(pErrInfo, VERR_GENERAL_FAILURE, "%s: Missing (%s).", pszErrorTag, RT_XSTR(RTASN1TMPL_TYPE)); \ int rc = VINF_SUCCESS # define RTASN1TMPL_END_COMMON() \ if (RT_SUCCESS(rc)) \ rc = (RTASN1TMPL_SANITY_CHECK_EXPR()); \ return rc; \ } RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_SEQCORE() RTASN1TMPL_BEGIN_COMMON() # define RTASN1TMPL_BEGIN_SETCORE() RTASN1TMPL_BEGIN_COMMON() # define RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, a_Constraints) \ if (RT_SUCCESS(rc)) \ { \ if (RT_LIKELY(RT_CONCAT(a_Api,_IsPresent)(&pThis->a_Name))) \ { \ rc = RT_CONCAT(a_Api,_CheckSanity)(&pThis->a_Name, fFlags & RTASN1_CHECK_SANITY_F_COMMON_MASK, \ pErrInfo, RT_XSTR(RTASN1TMPL_TYPE) "::" #a_Name); \ { a_Constraints } \ } \ else \ rc = RTErrInfoSetF(pErrInfo, VERR_GENERAL_FAILURE, "%s: Missing member %s (%s).", \ pszErrorTag, #a_Name, RT_XSTR(RTASN1TMPL_TYPE)); \ } do {} while (0) # define RTASN1TMPL_MEMBER_DYN_BEGIN(a_enmType, a_enmMembNm, a_Allocation) \ if (RT_SUCCESS(rc)) \ switch (pThis->a_enmMembNm) \ { \ default: \ rc = RTErrInfoSetF(pErrInfo, VERR_GENERAL_FAILURE, \ "%s: Invalid " #a_enmMembNm " value: %d", pszErrorTag, pThis->a_enmMembNm); \ break # define RTASN1TMPL_MEMBER_DYN_COMMON(a_UnionNm, a_PtrName, a_Type, a_Api, a_Allocation, a_enmMembNm, a_enmValue, a_IfStmt) \ case a_enmValue: \ rc = RT_CONCAT(a_Api,_CheckSanity)(pThis->a_UnionNm.a_PtrName, fFlags & RTASN1_CHECK_SANITY_F_COMMON_MASK, \ pErrInfo, RT_XSTR(RTASN1TMPL_TYPE) "::" #a_UnionNm "." #a_PtrName); \ break # define RTASN1TMPL_MEMBER_DYN_END(a_enmType, a_enmMembNm, a_Allocation) \ case RT_CONCAT(a_enmType,_NOT_PRESENT): \ rc = RTErrInfoSetF(pErrInfo, VERR_GENERAL_FAILURE, \ "%s: Invalid " #a_enmMembNm " value: " #a_enmType "_NOT_PRESENT", pszErrorTag); \ break; \ } # define RTASN1TMPL_MEMBER_OPT_EX(a_Name, a_Type, a_Api, a_Constraints) \ if (RT_SUCCESS(rc) && RT_CONCAT(a_Api,_IsPresent)(&pThis->a_Name)) \ { \ rc = RT_CONCAT(a_Api,_CheckSanity)(&pThis->a_Name, fFlags & RTASN1_CHECK_SANITY_F_COMMON_MASK, \ pErrInfo, RT_XSTR(RTASN1TMPL_TYPE) "::" #a_Name); \ { a_Constraints } \ } # define RTASN1TMPL_MEMBER_OPT_XTAG_EX(a_TnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_uTag, a_Constraints) \ if (RT_SUCCESS(rc)) \ { \ bool const fOuterPresent = RTASN1CORE_IS_PRESENT(&pThis->a_TnNm.a_CtxTagN.Asn1Core); \ bool const fInnerPresent = RT_CONCAT(a_Api,_IsPresent)(&pThis->a_TnNm.a_Name); \ if (fOuterPresent && fInnerPresent) \ { \ rc = RT_CONCAT(a_Api,_CheckSanity)(&pThis->a_TnNm.a_Name, fFlags & RTASN1_CHECK_SANITY_F_COMMON_MASK, \ pErrInfo, RT_XSTR(RTASN1TMPL_TYPE) "::" #a_Name); \ { a_Constraints } \ } \ else if (RT_LIKELY(RTASN1CORE_IS_PRESENT(&pThis->a_TnNm.a_CtxTagN.Asn1Core) == fInnerPresent)) \ { /* likely */ } \ else \ rc = RTErrInfoSetF(pErrInfo, VERR_GENERAL_FAILURE, \ "%s::" #a_TnNm "." #a_Name ": Explict tag precense mixup; " #a_CtxTagN "=%d " #a_Name "=%d.", \ pszErrorTag, fOuterPresent, fInnerPresent); \ } do { } while (0) # define RTASN1TMPL_END_SEQCORE() RTASN1TMPL_END_COMMON() # define RTASN1TMPL_END_SETCORE() RTASN1TMPL_END_COMMON() # define RTASN1TMPL_BEGIN_PCHOICE() \ RTASN1TMPL_BEGIN_COMMON(); \ switch (pThis->enmChoice) \ { \ default: \ rc = RTErrInfoSetF(pErrInfo, VERR_GENERAL_FAILURE, \ "%s: Invalid enmChoice value: %d", pszErrorTag, pThis->enmChoice); \ break # define RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, a_fClue, a_Constraints) \ case a_enmChoice: \ if (pThis->a_PtrName && RT_CONCAT(a_Api,_IsPresent)(pThis->a_PtrName)) \ { \ PCRTASN1CORE pCore = RT_CONCAT(a_Api,_GetAsn1Core)(pThis->a_PtrName); \ if (pCore->uTag == a_uTag && pCore->fClass == RTASN1TMPL_ITAG_F_EXPAND(a_fClue)) \ { \ rc = RT_CONCAT(a_Api,_CheckSanity)(pThis->a_PtrName, fFlags & RTASN1_CHECK_SANITY_F_COMMON_MASK, \ pErrInfo, RT_XSTR(RTASN1TMPL_TYPE) "::" #a_Name); \ { a_Constraints } \ } \ else \ rc = RTErrInfoSetF(pErrInfo, VERR_GENERAL_FAILURE, \ "%s::" #a_Name ": Tag/class mismatch: expected %#x/%#x, actual %#x/%x.", \ pszErrorTag, a_uTag, RTASN1TMPL_ITAG_F_EXPAND(a_fClue), pCore->uTag, pCore->fClass); \ } \ else \ rc = RTErrInfoSetF(pErrInfo, VERR_GENERAL_FAILURE, "%s::" #a_Name ": Not present.", pszErrorTag); \ break # define RTASN1TMPL_PCHOICE_XTAG_EX(a_uTag, a_enmChoice, a_PtrTnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_Constraints) \ case a_enmChoice: \ if ( pThis->a_PtrTnNm \ && RTASN1CORE_IS_PRESENT(&(pThis->a_PtrTnNm->a_CtxTagN.Asn1Core)) \ && RT_CONCAT(a_Api,_IsPresent)(&pThis->a_PtrTnNm->a_Name) ) \ { \ rc = RT_CONCAT(a_Api,_CheckSanity)(&pThis->a_PtrTnNm->a_Name, fFlags & RTASN1_CHECK_SANITY_F_COMMON_MASK, \ pErrInfo, RT_XSTR(RTASN1TMPL_TYPE) "::" #a_Name); \ { a_Constraints } \ } \ else \ rc = RTErrInfoSetF(pErrInfo, VERR_GENERAL_FAILURE, "%s::" #a_Name ": Not present.", pszErrorTag); \ break #define RTASN1TMPL_END_PCHOICE() \ } \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi) \ RTASN1TMPL_BEGIN_COMMON(); \ for (uint32_t i = 0; RT_SUCCESS(rc) && i < pThis->cItems; i++) \ rc = RT_CONCAT(a_ItemApi,_CheckSanity)(pThis->papItems[i], fFlags & RTASN1_CHECK_SANITY_F_COMMON_MASK, \ pErrInfo, RT_XSTR(RTASN1TMPL_TYPE) "::papItems[#]"); \ if (RT_SUCCESS(rc)) { RTASN1TMPL_SET_SEQ_EXEC_CHECK_SANITY(); } \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_SEQ_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi) # define RTASN1TMPL_SET_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi) /* The constraints. */ # define RTASN1TMPL_MEMBER_CONSTR_MIN_MAX(a_Name, a_Type, a_Api, cbMin, cbMax, a_MoreConstraints) \ if (RT_SUCCESS(rc) && ((cbMin) != 0 || (cbMax) != UINT32_MAX)) \ { \ PCRTASN1CORE pCore = RT_CONCAT(a_Api,_GetAsn1Core)(&pThis->a_Name); \ if (RT_LIKELY(pCore->cb >= (cbMin) && pCore->cb <= (cbMax))) \ { /* likely */ } \ else \ rc = RTErrInfoSetF(pErrInfo, VERR_GENERAL_FAILURE, \ "%s::" #a_Name ": Content size is out of range: %#x not in {%#x..%#x}", \ pszErrorTag, pCore->cb, cbMin, cbMax); \ } \ { a_MoreConstraints } # define RTASN1TMPL_MEMBER_CONSTR_BITSTRING_MIN_MAX(a_Name, cMinBits, cMaxBits, a_MoreConstraints) \ if (RT_SUCCESS(rc) && ((cMinBits) != 0 || (cMaxBits) != UINT32_MAX)) \ { \ if (RT_LIKELY( ((cMinBits) == 0 ? true : pThis->a_Name.cBits + 1U >= (cMinBits) + 1U /* warning avoiding */) \ && ((cMaxBits) == UINT32_MAX ? true : pThis->a_Name.cBits + 1U <= (cMaxBits) + 1U /* ditto */) ) ) \ { /* likely */ } \ else \ rc = RTErrInfoSetF(pErrInfo, VERR_GENERAL_FAILURE, \ "%s::" #a_Name ": Bit size is out of range: %#x not in {%#x..%#x}", \ pszErrorTag, pThis->a_Name.cBits, cMinBits, cMaxBits); \ } \ { a_MoreConstraints } # define RTASN1TMPL_MEMBER_CONSTR_U64_MIN_MAX(a_Name, uMin, uMax, a_MoreConstraints) \ if (RT_SUCCESS(rc)) \ { \ if (RT_LIKELY( RTAsn1Integer_UnsignedCompareWithU64(&pThis->a_Name, uMin) >= 0 \ && RTAsn1Integer_UnsignedCompareWithU64(&pThis->a_Name, uMax) <= 0) ) \ { /* likely */ } \ else \ rc = RTErrInfoSetF(pErrInfo, VERR_GENERAL_FAILURE, \ "%s::" #a_Name ": Out of range: %#x not in {%#llx..%#llx}", \ pszErrorTag, pThis->a_Name.Asn1Core.cb > 8 ? UINT64_MAX : pThis->a_Name.uValue.u, \ (uint64_t)(uMin), (uint64_t)(uMax)); \ } \ { a_MoreConstraints } # define RTASN1TMPL_MEMBER_CONSTR_PRESENT(a_Name, a_Api, a_MoreConstraints) \ if (RT_SUCCESS(rc)) \ { \ if (RT_LIKELY(RT_CONCAT(a_Api,_IsPresent)(&pThis->a_Name))) \ { /* likely */ } \ else \ rc = RTErrInfoSetF(pErrInfo, VERR_GENERAL_FAILURE, "%s::" #a_Name ": Missing.", pszErrorTag); \ } \ { a_MoreConstraints } # define RTASN1TMPL_EXEC_CHECK_SANITY(a_Expr) if (RT_SUCCESS(rc)) { a_Expr; } #elif RTASN1TMPL_PASS == RTASN1TMPL_PASS_DELETE /* * * Delete wrappers. * */ # define RTASN1TMPL_BEGIN_COMMON() \ RTASN1TMPL_DECL(void) RT_CONCAT(RTASN1TMPL_EXT_NAME,_Delete)(RT_CONCAT(P,RTASN1TMPL_TYPE) pThis) \ { \ if (RT_CONCAT(RTASN1TMPL_EXT_NAME,_IsPresent)(pThis)) \ { do { } while (0) # define RTASN1TMPL_END_COMMON() \ } \ RT_ZERO(*pThis); \ } RTASN1TMPL_SEMICOLON_DUMMY() # define RTASN1TMPL_BEGIN_SEQCORE() RTASN1TMPL_BEGIN_COMMON() # define RTASN1TMPL_BEGIN_SETCORE() RTASN1TMPL_BEGIN_COMMON() # define RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, a_Constraints) RT_CONCAT(a_Api,_Delete)(&pThis->a_Name) # define RTASN1TMPL_MEMBER_DYN_BEGIN(a_enmType, a_enmMembNm, a_Allocation) \ switch (pThis->a_enmMembNm) \ { \ default: break # define RTASN1TMPL_MEMBER_DYN_COMMON(a_UnionNm, a_PtrName, a_Type, a_Api, a_Allocation, a_enmMembNm, a_enmValue, a_IfStmt) \ case a_enmValue: \ if (pThis->a_UnionNm.a_PtrName) \ { \ RT_CONCAT(a_Api,_Delete)(pThis->a_UnionNm.a_PtrName); \ RTAsn1MemFree(&pThis->Allocation, pThis->a_UnionNm.a_PtrName); \ pThis->a_UnionNm.a_PtrName = NULL; \ } \ break # define RTASN1TMPL_MEMBER_DYN_END(a_enmType, a_enmMembNm, a_Allocation) \ } # define RTASN1TMPL_END_SEQCORE() RTASN1TMPL_END_COMMON() # define RTASN1TMPL_END_SETCORE() RTASN1TMPL_END_COMMON() # define RTASN1TMPL_BEGIN_PCHOICE() \ RTASN1TMPL_BEGIN_COMMON(); \ switch (pThis->enmChoice) \ { \ default: break # define RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, a_fClue, a_Constraints) \ case a_enmChoice: \ if (pThis->a_PtrName) \ { \ RT_CONCAT(a_Api,_Delete)(pThis->a_PtrName); \ RTAsn1MemFree(&pThis->Allocation, pThis->a_PtrName); \ pThis->a_PtrName = NULL; \ } \ break # define RTASN1TMPL_PCHOICE_XTAG_EX(a_uTag, a_enmChoice, a_PtrTnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_Constraints) \ case a_enmChoice: \ if (pThis->a_PtrTnNm) \ { \ RT_CONCAT(a_Api,_Delete)(&pThis->a_PtrTnNm->a_Name); \ RTAsn1MemFree(&pThis->Allocation, pThis->a_PtrTnNm); \ pThis->a_PtrTnNm = NULL; \ } \ break # define RTASN1TMPL_END_PCHOICE() \ } \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi) \ RTASN1TMPL_BEGIN_COMMON(); \ uint32_t i = pThis->cItems; \ while (i-- > 0) \ RT_CONCAT(a_ItemApi,_Delete)(pThis->papItems[i]); \ RTAsn1MemFreeArray(&pThis->Allocation, (void **)pThis->papItems); \ pThis->papItems = NULL; \ pThis->cItems = 0; \ RTASN1TMPL_END_COMMON() # define RTASN1TMPL_SEQ_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi) # define RTASN1TMPL_SET_OF(a_ItemType, a_ItemApi) RTASN1TMPL_SET_SEQ_OF_COMMON(a_ItemType, a_ItemApi) #else # error "Invalid/missing RTASN1TMPL_PASS value." #endif /* * Default aliases for simplified versions of macros if no specialization * was required above. */ /* Non-optional members. */ #ifndef RTASN1TMPL_MEMBER # define RTASN1TMPL_MEMBER(a_Name, a_Type, a_Api) \ RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_UTF8_STRING_MIN_MAX # define RTASN1TMPL_MEMBER_UTF8_STRING_MIN_MAX(a_Name) \ RTASN1TMPL_MEMBER(a_Name, RTASN1STRING, RTAsn1String) #endif #ifndef RTASN1TMPL_MEMBER_UTF8_STRING # define RTASN1TMPL_MEMBER_UTF8_STRING(a_Name) \ RTASN1TMPL_MEMBER_UTF8_STRING_MIN_MAX(a_Name, 0, UINT32_MAX) #endif #ifndef RTASN1TMPL_MEMBER_STRING_MIN_MAX # define RTASN1TMPL_MEMBER_STRING_MIN_MAX(a_Name, a_cbMin, a_cbMax) \ RTASN1TMPL_MEMBER(a_Name, RTASN1STRING, RTAsn1String) #endif #ifndef RTASN1TMPL_MEMBER_STRING # define RTASN1TMPL_MEMBER_STRING(a_Name) \ RTASN1TMPL_MEMBER_STRING_MIN_MAX(a_Name, 0, UINT32_MAX) #endif #ifndef RTASN1TMPL_MEMBER_XTAG_EX # define RTASN1TMPL_MEMBER_XTAG_EX(a_TnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_uTag, a_Constraints) \ RTASN1TMPL_MEMBER_EX(a_TnNm.a_Name, a_Type, a_Api, a_Constraints RT_NOTHING) #endif /* Any/dynamic members. */ #ifndef RTASN1TMPL_MEMBER_DYN_BEGIN # define RTASN1TMPL_MEMBER_DYN_BEGIN(a_enmType, a_enmMembNm, a_Allocation) do { } while (0) #endif #ifndef RTASN1TMPL_MEMBER_DYN_END # define RTASN1TMPL_MEMBER_DYN_END(a_enmType, a_enmMembNm, a_Allocation) do { } while (0) #endif #ifndef RTASN1TMPL_MEMBER_DYN_COMMON # define RTASN1TMPL_MEMBER_DYN_COMMON(a_UnionNm, a_PtrName, a_Type, a_Api, a_Allocation, a_enmMembNm, a_enmValue, a_IfStmt) \ RTASN1TMPL_MEMBER(a_UnionNm.a_PtrName, a_Type, a_Api) #endif #ifndef RTASN1TMPL_MEMBER_DYN # define RTASN1TMPL_MEMBER_DYN(a_UnionNm, a_PtrName, a_Type, a_Api, a_Allocation, a_enmMembNm, a_enmValue, a_WhenExpr) \ RTASN1TMPL_MEMBER_DYN_COMMON(a_UnionNm, a_PtrName, a_Type, a_Api, a_Allocation, a_enmMembNm, a_enmValue, if (a_WhenExpr)) #endif #ifndef RTASN1TMPL_MEMBER_DYN_DEFAULT # define RTASN1TMPL_MEMBER_DYN_DEFAULT(a_UnionNm, a_PtrName, a_Type, a_Api, a_Allocation, a_enmMembNm, a_enmValue) \ RTASN1TMPL_MEMBER_DYN_COMMON(a_UnionNm, a_PtrName, a_Type, a_Api, a_Allocation, a_enmMembNm, a_enmValue, RT_NOTHING) #endif /* Optional members. */ #ifndef RTASN1TMPL_MEMBER_OPT_EX # define RTASN1TMPL_MEMBER_OPT_EX(a_Name, a_Type, a_Api, a_Constraints) \ RTASN1TMPL_MEMBER_EX(a_Name, a_Type, a_Api, a_Constraints RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_OPT # define RTASN1TMPL_MEMBER_OPT(a_Name, a_Type, a_Api) \ RTASN1TMPL_MEMBER_OPT_EX(a_Name, a_Type, a_Api, RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_OPT_XTAG_EX # define RTASN1TMPL_MEMBER_OPT_XTAG_EX(a_TnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_uTag, a_Constraints) \ RTASN1TMPL_MEMBER_OPT_EX(a_TnNm.a_Name, a_Type, a_Api, a_Constraints RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_OPT_XTAG # define RTASN1TMPL_MEMBER_OPT_XTAG(a_TnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_uTag) \ RTASN1TMPL_MEMBER_OPT_XTAG_EX(a_TnNm, a_CtxTagN, a_Name, a_Type, a_Api, a_uTag, RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_OPT_ITAG_EX # define RTASN1TMPL_MEMBER_OPT_ITAG_EX(a_Name, a_Type, a_Api, a_uTag, a_fClue, a_Constraints) \ RTASN1TMPL_MEMBER_OPT_EX(a_Name, a_Type, a_Api, a_Constraints RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_OPT_ITAG_UP # define RTASN1TMPL_MEMBER_OPT_ITAG_UP(a_Name, a_Type, a_Api, a_uTag) \ RTASN1TMPL_MEMBER_OPT_ITAG_EX(a_Name, a_Type, a_Api, a_uTag, RTASN1TMPL_ITAG_F_UP, RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_OPT_ITAG_UC # define RTASN1TMPL_MEMBER_OPT_ITAG_UC(a_Name, a_Type, a_Api, a_uTag) \ RTASN1TMPL_MEMBER_OPT_ITAG_EX(a_Name, a_Type, a_Api, a_uTag, RTASN1TMPL_ITAG_F_UC, RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_OPT_ITAG_CP # define RTASN1TMPL_MEMBER_OPT_ITAG_CP(a_Name, a_Type, a_Api, a_uTag) \ RTASN1TMPL_MEMBER_OPT_ITAG_EX(a_Name, a_Type, a_Api, a_uTag, RTASN1TMPL_ITAG_F_CP, RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_OPT_ITAG # define RTASN1TMPL_MEMBER_OPT_ITAG(a_Name, a_Type, a_Api, a_uTag) \ RTASN1TMPL_MEMBER_OPT_ITAG_EX(a_Name, a_Type, a_Api, a_uTag, RTASN1TMPL_ITAG_F_CC, RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_OPT_ANY # define RTASN1TMPL_MEMBER_OPT_ANY(a_Name, a_Type, a_Api) \ RTASN1TMPL_MEMBER_OPT_EX(a_Name, a_Type, a_Api, RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_DEF_ITAG_EX # define RTASN1TMPL_MEMBER_DEF_ITAG_EX(a_Name, a_Type, a_Api, a_uTag, a_fClue, a_DefVal, a_Constraints) \ RTASN1TMPL_MEMBER_OPT_ITAG_EX(a_Name, a_Type, a_Api, a_uTag, a_fClue, a_Constraints RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_DEF_ITAG_UP # define RTASN1TMPL_MEMBER_DEF_ITAG_UP(a_Name, a_Type, a_Api, a_uTag, a_DefVal) \ RTASN1TMPL_MEMBER_DEF_ITAG_EX(a_Name, a_Type, a_Api, a_uTag, RTASN1TMPL_ITAG_F_UP, a_DefVal, RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_OPT_ITAG_BITSTRING # define RTASN1TMPL_MEMBER_OPT_ITAG_BITSTRING(a_Name, a_cMaxBits, a_uTag) \ RTASN1TMPL_MEMBER_OPT_ITAG_EX(a_Name, RTASN1BITSTRING, RTAsn1BitString, a_uTag, RTASN1TMPL_ITAG_F_CP, \ RTASN1TMPL_MEMBER_CONSTR_BITSTRING_MIN_MAX(a_Name, 0, a_cMaxBits, RT_NOTHING)) #endif #ifndef RTASN1TMPL_MEMBER_OPT_UTF8_STRING_EX # define RTASN1TMPL_MEMBER_OPT_UTF8_STRING_EX(a_Name, a_Constraints) \ RTASN1TMPL_MEMBER_OPT_EX(a_Name, RTASN1STRING, RTAsn1String, a_Constraints RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_OPT_UTF8_STRING # define RTASN1TMPL_MEMBER_OPT_UTF8_STRING(a_Name) \ RTASN1TMPL_MEMBER_OPT_UTF8_STRING_EX(a_Name, RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_OPT_STRING_EX # define RTASN1TMPL_MEMBER_OPT_STRING_EX(a_Name, a_Constraints) \ RTASN1TMPL_MEMBER_OPT_EX(a_Name, RTASN1STRING, RTAsn1String, a_Constraints RT_NOTHING) #endif #ifndef RTASN1TMPL_MEMBER_OPT_STRING # define RTASN1TMPL_MEMBER_OPT_STRING(a_Name) \ RTASN1TMPL_MEMBER_OPT_STRING_EX(a_Name, RT_NOTHING) #endif /* Pointer choices. */ #ifndef RTASN1TMPL_PCHOICE_ITAG_UP # define RTASN1TMPL_PCHOICE_ITAG_UP(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api) \ RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, RTASN1TMPL_ITAG_F_UP, RT_NOTHING) #endif #ifndef RTASN1TMPL_PCHOICE_ITAG_UC # define RTASN1TMPL_PCHOICE_ITAG_UC(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api) \ RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, RTASN1TMPL_ITAG_F_UC, RT_NOTHING) #endif #ifndef RTASN1TMPL_PCHOICE_ITAG_CP # define RTASN1TMPL_PCHOICE_ITAG_CP(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api) \ RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, RTASN1TMPL_ITAG_F_CP, RT_NOTHING) #endif #ifndef RTASN1TMPL_PCHOICE_ITAG # define RTASN1TMPL_PCHOICE_ITAG(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api) \ RTASN1TMPL_PCHOICE_ITAG_EX(a_uTag, a_enmChoice, a_PtrName, a_Name, a_Type, a_Api, RTASN1TMPL_ITAG_F_CC, RT_NOTHING) #endif #ifndef RTASN1TMPL_PCHOICE_XTAG # define RTASN1TMPL_PCHOICE_XTAG(a_uTag, a_enmChoice, a_PtrTnNm, a_CtxTagN, a_Name, a_Type, a_Api) \ RTASN1TMPL_PCHOICE_XTAG_EX(a_uTag, a_enmChoice, a_PtrTnNm, a_CtxTagN, a_Name, a_Type, a_Api, RT_NOTHING) #endif /* * Constraints are only used in the sanity check pass, so provide subs for the * others passes. */ #ifndef RTASN1TMPL_MEMBER_CONSTR_MIN_MAX # define RTASN1TMPL_MEMBER_CONSTR_MIN_MAX(a_Name, a_Type, a_Api, cbMin, cbMax, a_MoreConstraints) #endif #ifndef RTASN1TMPL_MEMBER_CONSTR_BITSTRING_MIN_MAX # define RTASN1TMPL_MEMBER_CONSTR_BITSTRING_MIN_MAX(a_Name, cMinBits, cMaxBits, a_MoreConstraints) #endif #ifndef RTASN1TMPL_MEMBER_CONSTR_U64_MIN_MAX # define RTASN1TMPL_MEMBER_CONSTR_U64_MIN_MAX(a_Name, uMin, uMax, a_MoreConstraints) #endif #ifndef RTASN1TMPL_MEMBER_CONSTR_PRESENT # define RTASN1TMPL_MEMBER_CONSTR_PRESENT(a_Name, a_Api, a_MoreConstraints) #endif /* * Stub exec hacks. */ #ifndef RTASN1TMPL_EXEC_DECODE # define RTASN1TMPL_EXEC_DECODE(a_Expr) /* no semi colon allowed after this */ #endif #ifndef RTASN1TMPL_EXEC_CLONE # define RTASN1TMPL_EXEC_CLONE(a_Expr) /* no semi colon allowed after this */ #endif #ifndef RTASN1TMPL_EXEC_CHECK_SANITY # define RTASN1TMPL_EXEC_CHECK_SANITY(a_Expr) /* no semi colon allowed after this */ #endif #define RTASN1TMPL_SET_SEQ_EXEC_CHECK_SANITY() do { } while (0) /* * Generate the requested code. */ #ifndef RTASN1TMPL_TEMPLATE_FILE # error "No template file (RTASN1TMPL_TEMPLATE_FILE) is specified." #endif #include RTASN1TMPL_TEMPLATE_FILE /* * Undo all the macros. */ #undef RTASN1TMPL_DECL #undef RTASN1TMPL_TYPE #undef RTASN1TMPL_EXT_NAME #undef RTASN1TMPL_INT_NAME #undef RTASN1TMPL_PASS #undef RTASN1TMPL_BEGIN_COMMON #undef RTASN1TMPL_END_COMMON #undef RTASN1TMPL_BEGIN_SEQCORE #undef RTASN1TMPL_BEGIN_SETCORE #undef RTASN1TMPL_MEMBER #undef RTASN1TMPL_MEMBER_EX #undef RTASN1TMPL_MEMBER_DYN_BEGIN #undef RTASN1TMPL_MEMBER_DYN #undef RTASN1TMPL_MEMBER_DYN_DEFAULT #undef RTASN1TMPL_MEMBER_DYN_COMMON #undef RTASN1TMPL_MEMBER_DYN_END #undef RTASN1TMPL_MEMBER_OPT #undef RTASN1TMPL_MEMBER_OPT_EX #undef RTASN1TMPL_MEMBER_OPT_ITAG #undef RTASN1TMPL_MEMBER_OPT_ITAG_EX #undef RTASN1TMPL_MEMBER_OPT_ITAG_CP #undef RTASN1TMPL_MEMBER_OPT_ITAG_UC #undef RTASN1TMPL_MEMBER_OPT_ITAG_UP #undef RTASN1TMPL_MEMBER_OPT_ITAG_BITSTRING #undef RTASN1TMPL_MEMBER_OPT_UTF8_STRING #undef RTASN1TMPL_MEMBER_OPT_UTF8_STRING_EX #undef RTASN1TMPL_MEMBER_OPT_XTAG #undef RTASN1TMPL_MEMBER_OPT_XTAG_EX #undef RTASN1TMPL_MEMBER_OPT_ANY #undef RTASN1TMPL_MEMBER_DEF_ITAG_UP #undef RTASN1TMPL_MEMBER_DEF_ITAG_EX #undef RTASN1TMPL_END_SEQCORE #undef RTASN1TMPL_END_SETCORE #undef RTASN1TMPL_BEGIN_PCHOICE #undef RTASN1TMPL_PCHOICE_ITAG #undef RTASN1TMPL_PCHOICE_ITAG_UP #undef RTASN1TMPL_PCHOICE_ITAG_CP #undef RTASN1TMPL_PCHOICE_ITAG_EX #undef RTASN1TMPL_PCHOICE_XTAG #undef RTASN1TMPL_PCHOICE_XTAG_EX #undef RTASN1TMPL_END_PCHOICE #undef RTASN1TMPL_SET_SEQ_OF_COMMON #undef RTASN1TMPL_SEQ_OF #undef RTASN1TMPL_SET_OF #undef RTASN1TMPL_VTABLE_FN_ENCODE_PREP #undef RTASN1TMPL_VTABLE_FN_ENCODE_WRITE #undef RTASN1TMPL_MEMBER_CONSTR_MIN_MAX #undef RTASN1TMPL_MEMBER_CONSTR_BITSTRING_MIN_MAX #undef RTASN1TMPL_MEMBER_CONSTR_U64_MIN_MAX #undef RTASN1TMPL_MEMBER_CONSTR_PRESENT #undef RTASN1TMPL_SANITY_CHECK_EXPR #undef RTASN1TMPL_EXEC_DECODE #undef RTASN1TMPL_EXEC_CLONE #undef RTASN1TMPL_EXEC_CHECK_SANITY #undef RTASN1TMPL_SET_SEQ_EXEC_CHECK_SANITY