-- $Id$ -- TEST DEFINITIONS ::= BEGIN IMPORTS heim_any FROM heim; -- Check that we handle out of order definitions. -- The compiler should emit the definition of TESTOutOfOrderBar before that of -- TESTOutOfOrderFoo. TESTOutOfOrderFoo ::= SEQUENCE { bar TESTOutOfOrderBar } TESTOutOfOrderBar ::= SEQUENCE { aMember INTEGER } -- Check that we can handle rpc.mountd style "lists". This is unnecessarily -- inefficient in its encoding, and there's no point to using this over -- SEQUENCE OF (arrays), but it's neat that we can do this now that we can do -- out of order definitions. -- -- This could be useful if we ever extend asn1_compile to also handle XDR, -- which we well might since XDR's syntax is a dual of a strict subset of -- ASN.1, and since XDR the encoding is fairly straightforward. -- -- Note that the `next' member has to be OPTIONAL for this to work. TESTCircular ::= SEQUENCE { name UTF8String, next TESTCircular OPTIONAL } TESTDefault ::= SEQUENCE { name UTF8String DEFAULT "Heimdal", version [0] TESTuint32 DEFAULT 8, maxint TESTuint64 DEFAULT 9223372036854775807, works BOOLEAN DEFAULT TRUE } TESTuint32 ::= INTEGER (0..4294967295) TESTuint64 ::= INTEGER(0..9223372036854775807) TESTint64 ::= INTEGER(-9223372036854775808..9223372036854775807) TESTLargeTag ::= SEQUENCE { foo[127] INTEGER (-2147483648..2147483647), bar[128] INTEGER (-2147483648..2147483647) } TESTSeq ::= SEQUENCE { tag0[0] INTEGER (-2147483648..2147483647), tag1[1] TESTLargeTag, tagless INTEGER (-2147483648..2147483647), tag3[2] INTEGER (-2147483648..2147483647) } TESTChoice1 ::= CHOICE { i1[1] INTEGER (-2147483648..2147483647), i2[2] INTEGER (-2147483648..2147483647), ... } TESTChoice2 ::= CHOICE { i1[1] INTEGER (-2147483648..2147483647), ... } TESTInteger ::= INTEGER (-2147483648..2147483647) TESTInteger2 ::= [4] IMPLICIT TESTInteger TESTInteger3 ::= [5] IMPLICIT TESTInteger2 TESTImplicit ::= SEQUENCE { ti1[0] IMPLICIT INTEGER (-2147483648..2147483647), ti2[1] IMPLICIT SEQUENCE { foo[127] INTEGER (-2147483648..2147483647) }, ti3[2] IMPLICIT [5] IMPLICIT [4] IMPLICIT INTEGER (-2147483648..2147483647) } TESTImplicit2 ::= SEQUENCE { ti1[0] IMPLICIT TESTInteger, -- ti2[1] IMPLICIT TESTLargeTag, this is disabled since the IMPLICT encoder does't get the types right when stepping inside an structure -- ti3[2] IMPLICIT TESTInteger3, ti4[51] IMPLICIT TESTInteger OPTIONAL } TESTImplicit3 ::= CHOICE { ti1[0] IMPLICIT INTEGER (-2147483648..2147483647), ti2[5] IMPLICIT CHOICE { i1[1] INTEGER (-2147483648..2147483647) } } TESTImplicit4 ::= CHOICE { ti1[0] IMPLICIT INTEGER (-2147483648..2147483647), ti2[5] IMPLICIT TESTChoice2 } TESTAllocInner ::= SEQUENCE { ai[0] TESTInteger } TESTAlloc ::= SEQUENCE { tagless TESTAllocInner OPTIONAL, three [1] INTEGER (-2147483648..2147483647), tagless2 heim_any OPTIONAL } TESTOptional ::= SEQUENCE { zero [0] INTEGER (-2147483648..2147483647) OPTIONAL, one [1] INTEGER (-2147483648..2147483647) OPTIONAL } TESTCONTAINING ::= OCTET STRING ( CONTAINING INTEGER ) TESTENCODEDBY ::= OCTET STRING ( ENCODED BY { joint-iso-itu-t(2) asn(1) ber-derived(2) distinguished-encoding(1) } ) TESTDer OBJECT IDENTIFIER ::= { joint-iso-itu-t(2) asn(1) ber-derived(2) distinguished-encoding(1) } TESTCONTAININGENCODEDBY ::= OCTET STRING ( CONTAINING INTEGER ENCODED BY { joint-iso-itu-t(2) asn(1) ber-derived(2) distinguished-encoding(1) } ) TESTCONTAININGENCODEDBY2 ::= OCTET STRING ( CONTAINING INTEGER ENCODED BY TESTDer ) TESTValue1 INTEGER ::= 1 TESTUSERCONSTRAINED ::= OCTET STRING (CONSTRAINED BY { -- meh -- }) -- TESTUSERCONSTRAINED2 ::= OCTET STRING (CONSTRAINED BY { TESTInteger }) -- TESTUSERCONSTRAINED3 ::= OCTET STRING (CONSTRAINED BY { INTEGER }) -- TESTUSERCONSTRAINED4 ::= OCTET STRING (CONSTRAINED BY { INTEGER : 1 }) TESTSeqOf ::= SEQUENCE OF TESTInteger TESTSeqSizeOf1 ::= SEQUENCE SIZE (2) OF TESTInteger TESTSeqSizeOf2 ::= SEQUENCE SIZE (1..2) OF TESTInteger TESTSeqSizeOf3 ::= SEQUENCE SIZE (1..MAX) OF TESTInteger TESTSeqSizeOf4 ::= SEQUENCE SIZE (0..2) OF TESTInteger TESTOSSize1 ::= OCTET STRING SIZE (1..2) TESTSeqOfSeq ::= SEQUENCE OF SEQUENCE { zero [0] TESTInteger } TESTSeqOfSeq2 ::= SEQUENCE OF SEQUENCE { string [0] GeneralString } TESTSeqOfSeq3 ::= SEQUENCE OF SEQUENCE { zero [0] TESTInteger, string [0] GeneralString } TESTSeqOf2 ::= SEQUENCE { strings SEQUENCE OF GeneralString } TESTSeqOf3 ::= SEQUENCE { strings SEQUENCE OF GeneralString OPTIONAL } -- Larger/more complex to increase odds of out-of-bounds -- read/writes if miscoded TESTSeqOf4 ::= SEQUENCE { b1 [0] SEQUENCE OF SEQUENCE { s1 OCTET STRING, s2 OCTET STRING, u1 TESTuint64, u2 TESTuint64 } OPTIONAL, b2 [1] IMPLICIT SEQUENCE OF SEQUENCE { u1 TESTuint64, u2 TESTuint64, u3 TESTuint64, s1 OCTET STRING, s2 OCTET STRING, s3 OCTET STRING } OPTIONAL, b3 [2] IMPLICIT SEQUENCE OF SEQUENCE { s1 OCTET STRING, u1 TESTuint64, s2 OCTET STRING, u2 TESTuint64, s3 OCTET STRING, u3 TESTuint64, s4 OCTET STRING, u4 TESTuint64 } OPTIONAL } TESTSeqOf5 ::= SEQUENCE { outer SEQUENCE { inner SEQUENCE { u0 TESTuint64, s0 OCTET STRING, u1 TESTuint64, s1 OCTET STRING, u2 TESTuint64, s2 OCTET STRING, u3 TESTuint64, s3 OCTET STRING, u4 TESTuint64, s4 OCTET STRING, u5 TESTuint64, s5 OCTET STRING, u6 TESTuint64, s6 OCTET STRING, u7 TESTuint64, s7 OCTET STRING } } OPTIONAL } TESTPreserve ::= SEQUENCE { zero [0] TESTInteger, one [1] TESTInteger } TESTBitString ::= BIT STRING { zero(0), eight(8), thirtyone(31) } TESTBitString64 ::= BIT STRING { zero(0), eight(8), thirtyone(31), thirtytwo(32), sixtythree(63) } TESTLargeBitString ::= BIT STRING { zero(0), eight(8), thirtyone(31), onehundredtwenty(120) } TESTMechType::= OBJECT IDENTIFIER TESTMechTypeList ::= SEQUENCE OF TESTMechType END