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samba-mirror/source4/build/pasn1/util.pm
Stefan Metzmacher 8991c6cd96 r1306: commit the first steps of my ASN.1 compiler
called 'pasn1', it works like 'pidl'

and we may can autogenerate ASN.1 code out of it.
(NOTE: the complete LDAP ASN.1 definition is in the RFC 2251,
 and maybe some others too :-)

I'm not completly shure if we'll use it in future,
but I commit it so that it won't be lost...

metze
(This used to be commit ddcaf7b63a)
2007-10-10 12:56:49 -05:00

380 lines
7.5 KiB
Perl

###################################################
# utility functions to support pidl
# Copyright tridge@samba.org 2000
# released under the GNU GPL
package util;
#####################################################################
# load a data structure from a file (as saved with SaveStructure)
sub LoadStructure($)
{
my $f = shift;
my $contents = FileLoad($f);
defined $contents || return undef;
return eval "$contents";
}
use strict;
#####################################################################
# flatten an array of arrays into a single array
sub FlattenArray2($)
{
my $a = shift;
my @b;
for my $d (@{$a}) {
for my $d1 (@{$d}) {
push(@b, $d1);
}
}
return \@b;
}
#####################################################################
# flatten an array of arrays into a single array
sub FlattenArray($)
{
my $a = shift;
my @b;
for my $d (@{$a}) {
for my $d1 (@{$d}) {
push(@b, $d1);
}
}
return \@b;
}
#####################################################################
# flatten an array of hashes into a single hash
sub FlattenHash($)
{
my $a = shift;
my %b;
for my $d (@{$a}) {
for my $k (keys %{$d}) {
$b{$k} = $d->{$k};
}
}
return \%b;
}
#####################################################################
# traverse a perl data structure removing any empty arrays or
# hashes and any hash elements that map to undef
sub CleanData($)
{
sub CleanData($);
my($v) = shift;
if (ref($v) eq "ARRAY") {
foreach my $i (0 .. $#{$v}) {
CleanData($v->[$i]);
if (ref($v->[$i]) eq "ARRAY" && $#{$v->[$i]}==-1) {
$v->[$i] = undef;
next;
}
}
# this removes any undefined elements from the array
@{$v} = grep { defined $_ } @{$v};
} elsif (ref($v) eq "HASH") {
foreach my $x (keys %{$v}) {
CleanData($v->{$x});
if (!defined $v->{$x}) { delete($v->{$x}); next; }
if (ref($v->{$x}) eq "ARRAY" && $#{$v->{$x}}==-1) { delete($v->{$x}); next; }
}
}
}
#####################################################################
# return the modification time of a file
sub FileModtime($)
{
my($filename) = shift;
return (stat($filename))[9];
}
#####################################################################
# read a file into a string
sub FileLoad($)
{
my($filename) = shift;
local(*INPUTFILE);
open(INPUTFILE, $filename) || return undef;
my($saved_delim) = $/;
undef $/;
my($data) = <INPUTFILE>;
close(INPUTFILE);
$/ = $saved_delim;
return $data;
}
#####################################################################
# write a string into a file
sub FileSave($$)
{
my($filename) = shift;
my($v) = shift;
local(*FILE);
open(FILE, ">$filename") || die "can't open $filename";
print FILE $v;
close(FILE);
}
#####################################################################
# return a filename with a changed extension
sub ChangeExtension($$)
{
my($fname) = shift;
my($ext) = shift;
if ($fname =~ /^(.*)\.(.*?)$/) {
return "$1$ext";
}
return "$fname$ext";
}
#####################################################################
# a dumper wrapper to prevent dependence on the Data::Dumper module
# unless we actually need it
sub MyDumper($)
{
require Data::Dumper;
my $s = shift;
return Data::Dumper::Dumper($s);
}
#####################################################################
# save a data structure into a file
sub SaveStructure($$)
{
my($filename) = shift;
my($v) = shift;
FileSave($filename, MyDumper($v));
}
#####################################################################
# see if a pidl property list contains a give property
sub has_property($$)
{
my($e) = shift;
my($p) = shift;
if (!defined $e->{PROPERTIES}) {
return undef;
}
return $e->{PROPERTIES}->{$p};
}
sub is_scalar_type($)
{
my($type) = shift;
if ($type =~ /^u?int\d+/) {
return 1;
}
if ($type =~ /char|short|long|NTTIME|
time_t|error_status_t|boolean32|unsigned32|
HYPER_T|wchar_t|DATA_BLOB/x) {
return 1;
}
return 0;
}
# return the NDR alignment for a type
sub type_align($)
{
my($e) = shift;
my $type = $e->{TYPE};
if (need_wire_pointer($e)) {
return 4;
}
return 4, if ($type eq "uint32");
return 4, if ($type eq "long");
return 2, if ($type eq "short");
return 1, if ($type eq "char");
return 1, if ($type eq "uint8");
return 2, if ($type eq "uint16");
return 4, if ($type eq "NTTIME");
return 4, if ($type eq "time_t");
return 8, if ($type eq "HYPER_T");
return 2, if ($type eq "wchar_t");
return 4, if ($type eq "DATA_BLOB");
# it must be an external type - all we can do is guess
return 4;
}
# this is used to determine if the ndr push/pull functions will need
# a ndr_flags field to split by buffers/scalars
sub is_builtin_type($)
{
my($type) = shift;
return 1, if (is_scalar_type($type));
return 0;
}
# determine if an element needs a reference pointer on the wire
# in its NDR representation
sub need_wire_pointer($)
{
my $e = shift;
if ($e->{POINTERS} &&
!has_property($e, "ref")) {
return $e->{POINTERS};
}
return undef;
}
# determine if an element is a pass-by-reference structure
sub is_ref_struct($)
{
my $e = shift;
if (!is_scalar_type($e->{TYPE}) &&
has_property($e, "ref")) {
return 1;
}
return 0;
}
# determine if an element is a pure scalar. pure scalars do not
# have a "buffers" section in NDR
sub is_pure_scalar($)
{
my $e = shift;
if (has_property($e, "ref")) {
return 1;
}
if (is_scalar_type($e->{TYPE}) &&
!$e->{POINTERS} &&
!array_size($e)) {
return 1;
}
return 0;
}
# determine the array size (size_is() or ARRAY_LEN)
sub array_size($)
{
my $e = shift;
my $size = has_property($e, "size_is");
if ($size) {
return $size;
}
$size = $e->{ARRAY_LEN};
if ($size) {
return $size;
}
return undef;
}
# see if a variable needs to be allocated by the NDR subsystem on pull
sub need_alloc($)
{
my $e = shift;
if (has_property($e, "ref")) {
return 0;
}
if ($e->{POINTERS} || array_size($e)) {
return 1;
}
return 0;
}
# determine the C prefix used to refer to a variable when passing to a push
# function. This will be '*' for pointers to scalar types, '' for scalar
# types and normal pointers and '&' for pass-by-reference structures
sub c_push_prefix($)
{
my $e = shift;
if ($e->{TYPE} =~ "string") {
return "";
}
if (is_scalar_type($e->{TYPE}) &&
$e->{POINTERS}) {
return "*";
}
if (!is_scalar_type($e->{TYPE}) &&
!$e->{POINTERS} &&
!array_size($e)) {
return "&";
}
return "";
}
# determine the C prefix used to refer to a variable when passing to a pull
# return '&' or ''
sub c_pull_prefix($)
{
my $e = shift;
if (!$e->{POINTERS} && !array_size($e)) {
return "&";
}
if ($e->{TYPE} =~ "string") {
return "&";
}
return "";
}
# determine if an element has a direct buffers component
sub has_direct_buffers($)
{
my $e = shift;
if ($e->{POINTERS} || array_size($e)) {
return 1;
}
return 0;
}
# return 1 if the string is a C constant
sub is_constant($)
{
my $s = shift;
if ($s =~ /^\d/) {
return 1;
}
return 0;
}
# return 1 if this is a fixed array
sub is_fixed_array($)
{
my $e = shift;
my $len = $e->{"ARRAY_LEN"};
if (defined $len && is_constant($len)) {
return 1;
}
return 0;
}
# return 1 if this is a inline array
sub is_inline_array($)
{
my $e = shift;
my $len = $e->{"ARRAY_LEN"};
if (is_fixed_array($e) ||
defined $len && $len ne "*") {
return 1;
}
return 0;
}
1;