################################################### # Samba4 NDR info tree generator # Copyright tridge@samba.org 2000-2003 # Copyright tpot@samba.org 2001 # Copyright jelmer@samba.org 2004-2006 # released under the GNU GPL =pod =head1 NAME Parse::Pidl::NDR - NDR parsing information generator =head1 DESCRIPTION Return a table describing the order in which the parts of an element should be parsed Possible level types: - POINTER - ARRAY - SUBCONTEXT - SWITCH - DATA =head1 AUTHOR Jelmer Vernooij =cut package Parse::Pidl::NDR; require Exporter; use vars qw($VERSION); $VERSION = '0.01'; @ISA = qw(Exporter); @EXPORT = qw(GetPrevLevel GetNextLevel ContainsDeferred ContainsString); use strict; use Parse::Pidl::Typelist qw(hasType getType expandAlias); use Parse::Pidl::Util qw(has_property property_matches); # Alignment of the built-in scalar types my $scalar_alignment = { 'void' => 0, 'char' => 1, 'int8' => 1, 'uint8' => 1, 'int16' => 2, 'uint16' => 2, 'int32' => 4, 'uint32' => 4, 'hyper' => 8, 'pointer' => 8, 'dlong' => 4, 'udlong' => 4, 'udlongr' => 4, 'DATA_BLOB' => 4, 'string' => 4, 'string_array' => 4, #??? 'time_t' => 4, 'NTTIME' => 4, 'NTTIME_1sec' => 4, 'NTTIME_hyper' => 8, 'WERROR' => 4, 'NTSTATUS' => 4, 'COMRESULT' => 4, 'nbt_string' => 4, 'wrepl_nbt_name' => 4, 'ipv4address' => 4 }; sub nonfatal($$) { my ($e,$s) = @_; warn ("$e->{FILE}:$e->{LINE}: Warning: $s\n"); } ##################################################################### # signal a fatal validation error sub fatal($$) { my ($pos,$s) = @_; die("$pos->{FILE}:$pos->{LINE}:$s\n"); } sub GetElementLevelTable($) { my $e = shift; my $order = []; my $is_deferred = 0; my @bracket_array = (); my @length_is = (); my @size_is = (); my $pointer_idx = 0; if (has_property($e, "size_is")) { @size_is = split /,/, has_property($e, "size_is"); } if (has_property($e, "length_is")) { @length_is = split /,/, has_property($e, "length_is"); } if (defined($e->{ARRAY_LEN})) { @bracket_array = @{$e->{ARRAY_LEN}}; } # Parse the [][][][] style array stuff for my $i (0 .. $#bracket_array) { my $d = $bracket_array[$#bracket_array - $i]; my $size = $d; my $length = $d; my $is_surrounding = 0; my $is_varying = 0; my $is_conformant = 0; my $is_string = 0; if ($d eq "*") { $is_conformant = 1; if ($size = shift @size_is) { } elsif ((scalar(@size_is) == 0) and has_property($e, "string")) { $is_string = 1; delete($e->{PROPERTIES}->{string}); } else { print "$e->{FILE}:$e->{LINE}: Must specify size_is() for conformant array!\n"; exit 1; } if (($length = shift @length_is) or $is_string) { $is_varying = 1; } else { $length = $size; } if ($e == $e->{PARENT}->{ELEMENTS}[-1] and $e->{PARENT}->{TYPE} ne "FUNCTION") { $is_surrounding = 1; } } push (@$order, { TYPE => "ARRAY", SIZE_IS => $size, LENGTH_IS => $length, IS_DEFERRED => "$is_deferred", IS_SURROUNDING => "$is_surrounding", IS_ZERO_TERMINATED => "$is_string", IS_VARYING => "$is_varying", IS_CONFORMANT => "$is_conformant", IS_FIXED => (not $is_conformant and Parse::Pidl::Util::is_constant($size)), IS_INLINE => (not $is_conformant and not Parse::Pidl::Util::is_constant($size)) }); } # Next, all the pointers foreach my $i (1..$e->{POINTERS}) { my $pt = pointer_type($e); my $level = "EMBEDDED"; # Top level "ref" pointers do not have a referrent identifier $level = "TOP" if ( defined($pt) and $i == 1 and $e->{PARENT}->{TYPE} eq "FUNCTION"); push (@$order, { TYPE => "POINTER", # for now, there can only be one pointer type per element POINTER_TYPE => pointer_type($e), POINTER_INDEX => $pointer_idx, IS_DEFERRED => "$is_deferred", LEVEL => $level }); $pointer_idx++; # everything that follows will be deferred $is_deferred = 1 if ($e->{PARENT}->{TYPE} ne "FUNCTION"); my $array_size = shift @size_is; my $array_length; my $is_varying; my $is_conformant; my $is_string = 0; if ($array_size) { $is_conformant = 1; if ($array_length = shift @length_is) { $is_varying = 1; } else { $array_length = $array_size; $is_varying =0; } } if (scalar(@size_is) == 0 and has_property($e, "string")) { $is_string = 1; $is_varying = $is_conformant = has_property($e, "noheader")?0:1; delete($e->{PROPERTIES}->{string}); } if ($array_size or $is_string) { push (@$order, { TYPE => "ARRAY", IS_ZERO_TERMINATED => "$is_string", SIZE_IS => $array_size, LENGTH_IS => $array_length, IS_DEFERRED => "$is_deferred", IS_SURROUNDING => 0, IS_VARYING => "$is_varying", IS_CONFORMANT => "$is_conformant", IS_FIXED => 0, IS_INLINE => 0, }); $is_deferred = 0; } } if (defined(has_property($e, "subcontext"))) { my $hdr_size = has_property($e, "subcontext"); my $subsize = has_property($e, "subcontext_size"); if (not defined($subsize)) { $subsize = -1; } push (@$order, { TYPE => "SUBCONTEXT", HEADER_SIZE => $hdr_size, SUBCONTEXT_SIZE => $subsize, IS_DEFERRED => $is_deferred, COMPRESSION => has_property($e, "compression"), }); } if (my $switch = has_property($e, "switch_is")) { push (@$order, { TYPE => "SWITCH", SWITCH_IS => $switch, IS_DEFERRED => $is_deferred }); } if (scalar(@size_is) > 0) { nonfatal($e, "size_is() on non-array element"); } if (scalar(@length_is) > 0) { nonfatal($e, "length_is() on non-array element"); } if (has_property($e, "string")) { nonfatal($e, "string() attribute on non-array element"); } push (@$order, { TYPE => "DATA", CONVERT_TO => has_property($e, ""), CONVERT_FROM => has_property($e, ""), DATA_TYPE => $e->{TYPE}, IS_DEFERRED => $is_deferred, CONTAINS_DEFERRED => can_contain_deferred($e), IS_SURROUNDING => 0 #FIXME }); my $i = 0; foreach (@$order) { $_->{LEVEL_INDEX} = $i; $i+=1; } return $order; } ##################################################################### # see if a type contains any deferred data sub can_contain_deferred { my $e = shift; return 0 if (Parse::Pidl::Typelist::is_scalar($e->{TYPE})); return 1 unless (hasType($e->{TYPE})); # assume the worst my $type = getType($e->{TYPE}); foreach my $x (@{$type->{DATA}->{ELEMENTS}}) { return 1 if ($x->{POINTERS}); return 1 if (can_contain_deferred ($x)); } return 0; } sub pointer_type($) { my $e = shift; return undef unless $e->{POINTERS}; return "ref" if (has_property($e, "ref")); return "ptr" if (has_property($e, "ptr")); return "sptr" if (has_property($e, "sptr")); return "unique" if (has_property($e, "unique")); return "relative" if (has_property($e, "relative")); return "ignore" if (has_property($e, "ignore")); return undef; } ##################################################################### # work out the correct alignment for a structure or union sub find_largest_alignment($) { my $s = shift; my $align = 1; for my $e (@{$s->{ELEMENTS}}) { my $a = 1; if ($e->{POINTERS}) { $a = 4; } elsif (has_property($e, "subcontext")) { $a = 1; } elsif (has_property($e, "transmit_as")) { $a = align_type($e->{PROPERTIES}->{transmit_as}); } else { $a = align_type($e->{TYPE}); } $align = $a if ($align < $a); } return $align; } ##################################################################### # align a type sub align_type($) { sub align_type($); my $e = shift; unless (hasType($e)) { # it must be an external type - all we can do is guess # print "Warning: assuming alignment of unknown type '$e' is 4\n"; return 4; } my $dt = getType($e)->{DATA}; if ($dt->{TYPE} eq "ENUM") { return align_type(Parse::Pidl::Typelist::enum_type_fn($dt)); } elsif ($dt->{TYPE} eq "BITMAP") { return align_type(Parse::Pidl::Typelist::bitmap_type_fn($dt)); } elsif (($dt->{TYPE} eq "STRUCT") or ($dt->{TYPE} eq "UNION")) { return find_largest_alignment($dt); } elsif ($dt->{TYPE} eq "SCALAR") { return $scalar_alignment->{$dt->{NAME}}; } die("Unknown data type type $dt->{TYPE}"); } sub ParseElement($) { my $e = shift; $e->{TYPE} = expandAlias($e->{TYPE}); return { NAME => $e->{NAME}, TYPE => $e->{TYPE}, PROPERTIES => $e->{PROPERTIES}, LEVELS => GetElementLevelTable($e), REPRESENTATION_TYPE => $e->{PROPERTIES}->{represent_as}, ALIGN => align_type($e->{TYPE}), ORIGINAL => $e }; } sub ParseStruct($$) { my ($ndr,$struct) = @_; my @elements = (); my $surrounding = undef; foreach my $x (@{$struct->{ELEMENTS}}) { my $e = ParseElement($x); if ($x != $struct->{ELEMENTS}[-1] and $e->{LEVELS}[0]->{IS_SURROUNDING}) { print "$x->{FILE}:$x->{LINE}: error: conformant member not at end of struct\n"; } push @elements, $e; } my $e = $elements[-1]; if (defined($e) and defined($e->{LEVELS}[0]->{IS_SURROUNDING}) and $e->{LEVELS}[0]->{IS_SURROUNDING}) { $surrounding = $e; } if (defined $e->{TYPE} && $e->{TYPE} eq "string" && property_matches($e, "flag", ".*LIBNDR_FLAG_STR_CONFORMANT.*")) { $surrounding = $struct->{ELEMENTS}[-1]; } return { TYPE => "STRUCT", SURROUNDING_ELEMENT => $surrounding, ELEMENTS => \@elements, PROPERTIES => $struct->{PROPERTIES}, ORIGINAL => $struct }; } sub ParseUnion($$) { my ($ndr,$e) = @_; my @elements = (); my $switch_type = has_property($e, "switch_type"); unless (defined($switch_type)) { $switch_type = "uint32"; } if (has_property($e, "nodiscriminant")) { $switch_type = undef; } my $hasdefault = 0; foreach my $x (@{$e->{ELEMENTS}}) { my $t; if ($x->{TYPE} eq "EMPTY") { $t = { TYPE => "EMPTY" }; } else { $t = ParseElement($x); } if (has_property($x, "default")) { $t->{CASE} = "default"; $hasdefault = 1; } elsif (defined($x->{PROPERTIES}->{case})) { $t->{CASE} = "case $x->{PROPERTIES}->{case}"; } else { die("Union element $x->{NAME} has neither default nor case property"); } push @elements, $t; } return { TYPE => "UNION", SWITCH_TYPE => $switch_type, ELEMENTS => \@elements, PROPERTIES => $e->{PROPERTIES}, HAS_DEFAULT => $hasdefault, ORIGINAL => $e }; } sub ParseEnum($$) { my ($ndr,$e) = @_; return { TYPE => "ENUM", BASE_TYPE => Parse::Pidl::Typelist::enum_type_fn($e), ELEMENTS => $e->{ELEMENTS}, PROPERTIES => $e->{PROPERTIES}, ORIGINAL => $e }; } sub ParseBitmap($$) { my ($ndr,$e) = @_; return { TYPE => "BITMAP", BASE_TYPE => Parse::Pidl::Typelist::bitmap_type_fn($e), ELEMENTS => $e->{ELEMENTS}, PROPERTIES => $e->{PROPERTIES}, ORIGINAL => $e }; } sub ParseType($$) { my ($ndr, $d) = @_; if ($d->{TYPE} eq "STRUCT" or $d->{TYPE} eq "UNION") { CheckPointerTypes($d, $ndr->{PROPERTIES}->{pointer_default}); } my $data = { STRUCT => \&ParseStruct, UNION => \&ParseUnion, ENUM => \&ParseEnum, BITMAP => \&ParseBitmap, TYPEDEF => \&ParseTypedef, }->{$d->{TYPE}}->($ndr, $d); return $data; } sub ParseTypedef($$) { my ($ndr,$d) = @_; if (defined($d->{PROPERTIES}) && !defined($d->{DATA}->{PROPERTIES})) { $d->{DATA}->{PROPERTIES} = $d->{PROPERTIES}; } my $data = ParseType($ndr, $d->{DATA}); $data->{ALIGN} = align_type($d->{NAME}); return { NAME => $d->{NAME}, TYPE => $d->{TYPE}, PROPERTIES => $d->{PROPERTIES}, DATA => $data, ORIGINAL => $d }; } sub ParseConst($$) { my ($ndr,$d) = @_; return $d; } sub ParseFunction($$$) { my ($ndr,$d,$opnum) = @_; my @elements = (); my $rettype = undef; my $thisopnum = undef; CheckPointerTypes($d, $ndr->{PROPERTIES}->{pointer_default_top}); if (not defined($d->{PROPERTIES}{noopnum})) { $thisopnum = ${$opnum}; ${$opnum}++; } foreach my $x (@{$d->{ELEMENTS}}) { my $e = ParseElement($x); push (@{$e->{DIRECTION}}, "in") if (has_property($x, "in")); push (@{$e->{DIRECTION}}, "out") if (has_property($x, "out")); nonfatal($x, "`$e->{NAME}' is [out] argument but not a pointer or array") if ($e->{LEVELS}[0]->{TYPE} ne "POINTER" and $e->{LEVELS}[0]->{TYPE} ne "ARRAY" and grep(/out/, @{$e->{DIRECTION}})); push (@elements, $e); } if ($d->{RETURN_TYPE} ne "void") { $rettype = expandAlias($d->{RETURN_TYPE}); } my $async = 0; if (has_property($d, "async")) { $async = 1; } return { NAME => $d->{NAME}, TYPE => "FUNCTION", OPNUM => $thisopnum, ASYNC => $async, RETURN_TYPE => $rettype, PROPERTIES => $d->{PROPERTIES}, ELEMENTS => \@elements, ORIGINAL => $d }; } sub CheckPointerTypes($$) { my ($s,$default) = @_; foreach my $e (@{$s->{ELEMENTS}}) { if ($e->{POINTERS} and not defined(pointer_type($e))) { $e->{PROPERTIES}->{$default} = 1; } } } #FIXME: Remove when ref handling in Samba4 is fixed sub AddKeepRef($) { my $d = shift; if ($d->{TYPE} eq "FUNCTION") { foreach (@{$d->{ELEMENTS}}) { $_->{PROPERTIES}->{keepref} = 1; } } elsif ($d->{TYPE} eq "TYPEDEF" and ($d->{DATA}->{TYPE} eq "STRUCT" or $d->{DATA}->{TYPE} eq "UNION")) { foreach (@{$d->{DATA}->{ELEMENTS}}) { $_->{PROPERTIES}->{keepref} = 1; } } } sub ParseInterface($) { my $idl = shift; my @types = (); my @consts = (); my @functions = (); my @endpoints; my @declares = (); my $opnum = 0; my $version; if (not has_property($idl, "pointer_default")) { # MIDL defaults to "ptr" in DCE compatible mode (/osf) # and "unique" in Microsoft Extensions mode (default) $idl->{PROPERTIES}->{pointer_default} = "unique"; } if (not has_property($idl, "pointer_default_top")) { $idl->{PROPERTIES}->{pointer_default_top} = "ref"; } foreach my $d (@{$idl->{DATA}}) { if ($d->{TYPE} eq "DECLARE") { push (@declares, $d); } elsif ($d->{TYPE} eq "FUNCTION") { AddKeepRef($d) if (has_property($idl, "keepref")); push (@functions, ParseFunction($idl, $d, \$opnum)); } elsif ($d->{TYPE} eq "CONST") { push (@consts, ParseConst($idl, $d)); } else { AddKeepRef($d) if (has_property($idl, "keepref")); push (@types, ParseType($idl, $d)); } } $version = "0.0"; if(defined $idl->{PROPERTIES}->{version}) { $version = $idl->{PROPERTIES}->{version}; } # If no endpoint is set, default to the interface name as a named pipe if (!defined $idl->{PROPERTIES}->{endpoint}) { push @endpoints, "\"ncacn_np:[\\\\pipe\\\\" . $idl->{NAME} . "]\""; } else { @endpoints = split / /, $idl->{PROPERTIES}->{endpoint}; } return { NAME => $idl->{NAME}, UUID => lc(has_property($idl, "uuid")), VERSION => $version, TYPE => "INTERFACE", PROPERTIES => $idl->{PROPERTIES}, FUNCTIONS => \@functions, CONSTS => \@consts, TYPES => \@types, DECLARES => \@declares, ENDPOINTS => \@endpoints }; } # Convert a IDL tree to a NDR tree # Gives a result tree describing all that's necessary for easily generating # NDR parsers / generators sub Parse($) { my $idl = shift; return undef unless (defined($idl)); Parse::Pidl::NDR::Validate($idl); my @ndr = (); foreach (@{$idl}) { ($_->{TYPE} eq "INTERFACE") && push(@ndr, ParseInterface($_)); } return \@ndr; } sub GetNextLevel($$) { my $e = shift; my $fl = shift; my $seen = 0; foreach my $l (@{$e->{LEVELS}}) { return $l if ($seen); ($seen = 1) if ($l == $fl); } return undef; } sub GetPrevLevel($$) { my ($e,$fl) = @_; my $prev = undef; foreach my $l (@{$e->{LEVELS}}) { (return $prev) if ($l == $fl); $prev = $l; } return undef; } sub ContainsString($) { my ($e) = @_; foreach my $l (@{$e->{LEVELS}}) { return 1 if ($l->{TYPE} eq "ARRAY" and $l->{IS_ZERO_TERMINATED}); } return 0; } sub ContainsDeferred($$) { my ($e,$l) = @_; return 1 if ($l->{CONTAINS_DEFERRED}); while ($l = GetNextLevel($e,$l)) { return 1 if ($l->{IS_DEFERRED}); return 1 if ($l->{CONTAINS_DEFERRED}); } return 0; } sub el_name($) { my $e = shift; if ($e->{PARENT} && $e->{PARENT}->{NAME}) { return "$e->{PARENT}->{NAME}.$e->{NAME}"; } if ($e->{PARENT} && $e->{PARENT}->{PARENT}->{NAME}) { return "$e->{PARENT}->{PARENT}->{NAME}.$e->{NAME}"; } if ($e->{PARENT}) { return "$e->{PARENT}->{NAME}.$e->{NAME}"; } return $e->{NAME}; } ################################### # find a sibling var in a structure sub find_sibling($$) { my($e,$name) = @_; my($fn) = $e->{PARENT}; if ($name =~ /\*(.*)/) { $name = $1; } for my $e2 (@{$fn->{ELEMENTS}}) { return $e2 if ($e2->{NAME} eq $name); } return undef; } my %property_list = ( # interface "helpstring" => ["INTERFACE", "FUNCTION"], "version" => ["INTERFACE"], "uuid" => ["INTERFACE"], "endpoint" => ["INTERFACE"], "pointer_default" => ["INTERFACE"], "pointer_default_top" => ["INTERFACE"], "depends" => ["INTERFACE"], "helper" => ["INTERFACE"], "authservice" => ["INTERFACE"], # dcom "object" => ["INTERFACE"], "local" => ["INTERFACE", "FUNCTION"], "iid_is" => ["ELEMENT"], "call_as" => ["FUNCTION"], "idempotent" => ["FUNCTION"], # function "noopnum" => ["FUNCTION"], "in" => ["ELEMENT"], "out" => ["ELEMENT"], "async" => ["FUNCTION"], # pointer "ref" => ["ELEMENT"], "ptr" => ["ELEMENT"], "sptr" => ["ELEMENT"], "unique" => ["ELEMENT"], "ignore" => ["ELEMENT"], "relative" => ["ELEMENT"], "relative_base" => ["TYPEDEF"], "gensize" => ["TYPEDEF"], "value" => ["ELEMENT"], "flag" => ["ELEMENT", "TYPEDEF"], # generic "public" => ["FUNCTION", "TYPEDEF"], "nopush" => ["FUNCTION", "TYPEDEF"], "nopull" => ["FUNCTION", "TYPEDEF"], "nosize" => ["FUNCTION", "TYPEDEF"], "noprint" => ["FUNCTION", "TYPEDEF"], "noejs" => ["FUNCTION", "TYPEDEF"], # union "switch_is" => ["ELEMENT"], "switch_type" => ["ELEMENT", "TYPEDEF"], "nodiscriminant" => ["TYPEDEF"], "case" => ["ELEMENT"], "default" => ["ELEMENT"], "represent_as" => ["ELEMENT"], "transmit_as" => ["ELEMENT"], # subcontext "subcontext" => ["ELEMENT"], "subcontext_size" => ["ELEMENT"], "compression" => ["ELEMENT"], # enum "enum8bit" => ["TYPEDEF"], "enum16bit" => ["TYPEDEF"], "v1_enum" => ["TYPEDEF"], # bitmap "bitmap8bit" => ["TYPEDEF"], "bitmap16bit" => ["TYPEDEF"], "bitmap32bit" => ["TYPEDEF"], "bitmap64bit" => ["TYPEDEF"], # array "range" => ["ELEMENT"], "size_is" => ["ELEMENT"], "string" => ["ELEMENT"], "noheader" => ["ELEMENT"], "charset" => ["ELEMENT"], "length_is" => ["ELEMENT"], # temporary (should be removed once we've migrated away from # relying on ref pointers being there in Samba4's code) "keepref" => ["ELEMENT","INTERFACE"], ); ##################################################################### # check for unknown properties sub ValidProperties($$) { my ($e,$t) = @_; return unless defined $e->{PROPERTIES}; foreach my $key (keys %{$e->{PROPERTIES}}) { fatal($e, el_name($e) . ": unknown property '$key'\n") unless defined($property_list{$key}); fatal($e, el_name($e) . ": property '$key' not allowed on '$t'\n") unless grep($t, @{$property_list{$key}}); } } sub mapToScalar($) { my $t = shift; my $ti = getType($t); if (not defined ($ti)) { return undef; } elsif ($ti->{DATA}->{TYPE} eq "ENUM") { return Parse::Pidl::Typelist::enum_type_fn($ti->{DATA}); } elsif ($ti->{DATA}->{TYPE} eq "BITMAP") { return Parse::Pidl::Typelist::enum_type_fn($ti->{DATA}); } elsif ($ti->{DATA}->{TYPE} eq "SCALAR") { return $t; } return undef; } ##################################################################### # parse a struct sub ValidElement($) { my $e = shift; ValidProperties($e,"ELEMENT"); if (has_property($e, "ptr")) { fatal($e, el_name($e) . " : pidl does not support full NDR pointers yet\n"); } # Check whether switches are used correctly. if (my $switch = has_property($e, "switch_is")) { my $e2 = find_sibling($e, $switch); my $type = getType($e->{TYPE}); if (defined($type) and $type->{DATA}->{TYPE} ne "UNION") { fatal($e, el_name($e) . ": switch_is() used on non-union type $e->{TYPE} which is a $type->{DATA}->{TYPE}"); } if (!has_property($type, "nodiscriminant") and defined($e2)) { my $discriminator_type = has_property($type, "switch_type"); $discriminator_type = "uint32" unless defined ($discriminator_type); my $t1 = mapToScalar($discriminator_type); if (not defined($t1)) { fatal($e, el_name($e) . ": unable to map discriminator type '$discriminator_type' to scalar"); } my $t2 = mapToScalar($e2->{TYPE}); if (not defined($t2)) { fatal($e, el_name($e) . ": unable to map variable used for switch_is() to scalar"); } if ($t1 ne $t2) { nonfatal($e, el_name($e) . ": switch_is() is of type $e2->{TYPE} ($t2), while discriminator type for union $type->{NAME} is $discriminator_type ($t1)"); } } } if (has_property($e, "subcontext") and has_property($e, "represent_as")) { fatal($e, el_name($e) . " : subcontext() and represent_as() can not be used on the same element"); } if (has_property($e, "subcontext") and has_property($e, "transmit_as")) { fatal($e, el_name($e) . " : subcontext() and transmit_as() can not be used on the same element"); } if (has_property($e, "represent_as") and has_property($e, "transmit_as")) { fatal($e, el_name($e) . " : represent_as() and transmit_as() can not be used on the same element"); } if (has_property($e, "represent_as") and has_property($e, "value")) { fatal($e, el_name($e) . " : represent_as() and value() can not be used on the same element"); } if (defined (has_property($e, "subcontext_size")) and not defined(has_property($e, "subcontext"))) { fatal($e, el_name($e) . " : subcontext_size() on non-subcontext element"); } if (defined (has_property($e, "compression")) and not defined(has_property($e, "subcontext"))) { fatal($e, el_name($e) . " : compression() on non-subcontext element"); } if (!$e->{POINTERS} && ( has_property($e, "ptr") or has_property($e, "sptr") or has_property($e, "unique") or has_property($e, "relative") or has_property($e, "ref"))) { fatal($e, el_name($e) . " : pointer properties on non-pointer element\n"); } } ##################################################################### # parse a struct sub ValidStruct($) { my($struct) = shift; ValidProperties($struct,"STRUCT"); foreach my $e (@{$struct->{ELEMENTS}}) { $e->{PARENT} = $struct; ValidElement($e); } } ##################################################################### # parse a union sub ValidUnion($) { my($union) = shift; ValidProperties($union,"UNION"); if (has_property($union->{PARENT}, "nodiscriminant") and has_property($union->{PARENT}, "switch_type")) { fatal($union->{PARENT}, $union->{PARENT}->{NAME} . ": switch_type() on union without discriminant"); } foreach my $e (@{$union->{ELEMENTS}}) { $e->{PARENT} = $union; if (defined($e->{PROPERTIES}->{default}) and defined($e->{PROPERTIES}->{case})) { fatal $e, "Union member $e->{NAME} can not have both default and case properties!\n"; } unless (defined ($e->{PROPERTIES}->{default}) or defined ($e->{PROPERTIES}->{case})) { fatal $e, "Union member $e->{NAME} must have default or case property\n"; } if (has_property($e, "ref")) { fatal($e, el_name($e) . " : embedded ref pointers are not supported yet\n"); } ValidElement($e); } } ##################################################################### # parse a typedef sub ValidTypedef($) { my($typedef) = shift; my $data = $typedef->{DATA}; ValidProperties($typedef,"TYPEDEF"); $data->{PARENT} = $typedef; if (ref($data) eq "HASH") { if ($data->{TYPE} eq "STRUCT") { ValidStruct($data); } if ($data->{TYPE} eq "UNION") { ValidUnion($data); } } } ##################################################################### # parse a function sub ValidFunction($) { my($fn) = shift; ValidProperties($fn,"FUNCTION"); foreach my $e (@{$fn->{ELEMENTS}}) { $e->{PARENT} = $fn; if (has_property($e, "ref") && !$e->{POINTERS}) { fatal $e, "[ref] variables must be pointers ($fn->{NAME}/$e->{NAME})\n"; } ValidElement($e); } } ##################################################################### # parse the interface definitions sub ValidInterface($) { my($interface) = shift; my($data) = $interface->{DATA}; ValidProperties($interface,"INTERFACE"); if (has_property($interface, "pointer_default") && $interface->{PROPERTIES}->{pointer_default} eq "ptr") { fatal $interface, "Full pointers are not supported yet\n"; } if (has_property($interface, "object")) { if (has_property($interface, "version") && $interface->{PROPERTIES}->{version} != 0) { fatal $interface, "Object interfaces must have version 0.0 ($interface->{NAME})\n"; } if (!defined($interface->{BASE}) && not ($interface->{NAME} eq "IUnknown")) { fatal $interface, "Object interfaces must all derive from IUnknown ($interface->{NAME})\n"; } } foreach my $d (@{$data}) { ($d->{TYPE} eq "TYPEDEF") && ValidTypedef($d); ($d->{TYPE} eq "FUNCTION") && ValidFunction($d); } } ##################################################################### # Validate an IDL structure sub Validate($) { my($idl) = shift; foreach my $x (@{$idl}) { ($x->{TYPE} eq "INTERFACE") && ValidInterface($x); } } 1;