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Simba/Units/Misc/bzip2.pas

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unit bzip2;
{****************************************************************************
BZIP2 decompression unit
Copyright (C) 2002 by Daniel Mantione
This unit provides a decompression stream to decode .bz2 files. It is
inpired by Julian R. Seward's libbzip2 library and therefore you should
send credits to him and bug reports to me :)
This code is licensed under the same terms as the original libbz2 library,
which is decsribed in the file LICENSE. If you don't have this file, look
at http://www.freepascal.org for this bzip2 unit, the LICENSE file will
be included. In case of problems, contact the author.
E-mail addresses:
Daniel Mantione <daniel.mantione@freepascal.org>
Julian R. Seward <jseward@acm.org>
Please do not contact Julian about this Pascal library, he didn't wrote it.
****************************************************************************}
interface
{$goto on}
uses objects, bzip2comn,classes;
Type
pstream = ^classes.tstream;
Tbzip2_decode_stream=object(objects.Tstream)
short:cardinal;
readstream:pstream;
block_randomized:boolean;
blocksize:byte;
tt:Pcardinal_array;
tt_count:cardinal;
rle_run_left,rle_run_data:byte;
nextrle:Pbyte;
decode_available:cardinal;
block_origin:cardinal;
current_block:cardinal;
read_data,bits_available:byte;
inuse16:set of 0..15;
inuse:set of 0..255;
inuse_count:cardinal;
seq_to_unseq:array[0..255] of byte;
alphasize:cardinal;
group_count,group_pos,gsel,gminlen:byte;
group_no:cardinal;
glimit,gperm,gbase:Phuffarray;
selector_count:cardinal;
selector,selector_mtf:array[0..max_selectors] of byte;
len:array[0..max_groups,0..max_alpha_size] of byte;
limit:array[0..max_groups,0..max_alpha_size] of cardinal;
base:array[0..max_groups,0..max_alpha_size] of cardinal;
perm:array[0..max_groups,0..max_alpha_size] of cardinal;
minlens:array[0..max_groups] of byte;
cftab:array[0..257] of cardinal;
mtfbase:array[0..256 div mtfl_size-1] of cardinal;
mtfa:array[0..mtfa_size-1] of byte;
constructor init(Areadstream:pstream);
function get_bits(n:byte):byte;
function get_boolean:boolean;
function get_byte:byte;
function get_cardinal24:cardinal;
function get_cardinal:cardinal;
procedure receive_mapping_table;
procedure receive_selectors;
procedure undo_mtf_values;
procedure receive_coding_tables;
procedure make_hufftab;
procedure init_mtf;
function get_mtf_value:cardinal;
procedure move_mtf_block;
procedure receive_mtf_values;
procedure detransform;
function decode_block:boolean;
procedure read(var buf;count:Longint);virtual;
procedure new_block;
procedure consume_rle;inline;
procedure rle_read(bufptr:Pbyte;var count:Longint);
destructor done;virtual;
end;
implementation
{$ifdef i386}
{$i bzip2i386.inc}
{$endif}
{*****************************************************************************
Tbzip2_decode_stream
*****************************************************************************}
constructor Tbzip2_decode_stream.init(Areadstream:pstream);
var magic:array[1..3] of char;
c:char;
begin
readstream:=Areadstream;
{Read the magic.}
readstream^.read(magic,sizeof(magic));
if magic<>bzip2_stream_magic then
begin
error(stiniterror,bzip2_bad_header_magic);
exit;
end;
{Read the block size and allocate the working array.}
readstream^.read(c,1);
blocksize:=byte(c)-byte('0');
getmem(tt,blocksize*100000*sizeof(cardinal));
decode_available:=high(decode_available);
end;
function Tbzip2_decode_stream.get_bits(n:byte):byte;
var data:byte;
begin
if n>bits_available then
begin
readstream^.read(data,1);
get_bits:=(read_data shr (8-n)) or data shr (8-(n-bits_available));
read_data:=data shl (n-bits_available);
inc(bits_available,8);
end
else
begin
get_bits:=read_data shr (8-n);
read_data:=read_data shl n;
end;
dec(bits_available,n);
end;
function Tbzip2_decode_stream.get_boolean:boolean;
begin
get_boolean:=boolean(get_bits(1));
end;
function Tbzip2_decode_stream.get_byte:byte;
begin
get_byte:=get_bits(8);
end;
function Tbzip2_decode_stream.get_cardinal24:cardinal;
begin
get_cardinal24:=get_bits(8) shl 16 or get_bits(8) shl 8 or get_bits(8);
end;
function Tbzip2_decode_stream.get_cardinal:cardinal;
begin
get_cardinal:=get_bits(8) shl 24 or get_bits(8) shl 16 or get_bits(8) shl 8 or
get_bits(8);
end;
procedure Tbzip2_decode_stream.receive_mapping_table;
{Receive the mapping table. To save space, the inuse set is stored in pieces
of 16 bits. First 16 bits are stored which pieces of 16 bits are used, then
the pieces follow.}
var i,j:byte;
begin
inuse16:=[];
{Receive the first 16 bits which tell which pieces are stored.}
for i:=0 to 15 do
if get_boolean then
include(inuse16,i);
{Receive the used pieces.}
inuse:=[];
inuse_count:=0;
for i:=0 to 15 do
if i in inuse16 then
for j:=0 to 15 do
if get_boolean then
begin
include(inuse,16*i+j);
seq_to_unseq[inuse_count]:=16*i+j;
inc(inuse_count);
end;
{ system.write('Mapping table: ');
for i:=0 to 255 do
if i in inuse then
system.write(i,' ');
writeln;}
end;
procedure Tbzip2_decode_stream.receive_selectors;
{Receives the selectors.}
var i:cardinal;
j:byte;
begin
group_count:=get_bits(3);
selector_count:=get_bits(8) shl 7 or get_bits(7);
for i:=0 to selector_count-1 do
begin
j:=0;
while get_boolean do
begin
inc(j);
if j>5 then
error(streaderror,bzip2_data_error);
end;
selector_mtf[i]:=j;
end;
{ system.write('Selector_mtf: ');
for i:=0 to selector_count-1 do
system.write(selector_mtf[i],' ');
writeln;}
end;
procedure Tbzip2_decode_stream.undo_mtf_values;
{Undo the MTF values for the selectors.}
var pos:array[0..max_groups] of byte;
i:cardinal;
v,tmp:byte;
begin
for v:=0 to group_count-1 do
pos[v]:=v;
for i:=0 to selector_count-1 do
begin
v:=selector_mtf[i];
tmp:=pos[v];
while v<>0 do
begin
pos[v]:=pos[v-1];
dec(v);
end;
pos[0]:=tmp;
selector[i]:=tmp;
end;
end;
procedure Tbzip2_decode_stream.receive_coding_tables;
var t,curr:byte;
i:cardinal;
begin
for t:=0 to group_count-1 do
begin
curr:=get_bits(5);
for i:=0 to alphasize-1 do
begin
repeat
if not(curr in [1..20]) then
begin
error(streaderror,bzip2_data_error);
exit;
end;
if not get_boolean then
break;
if get_boolean then
dec(curr)
else
inc(curr);
until false;
len[t,i]:=curr;
end;
end;
{ writeln('Coding tables:');
for t:=0 to group_count-1 do
begin
for i:=0 to alphasize-1 do
system.write(len[t,i],' ');
writeln;
end;}
end;
procedure Tbzip2_decode_stream.make_hufftab;
{Builds the Huffman tables.}
var i:cardinal;
t,minlen,maxlen:byte;
begin
for t:=0 to group_count-1 do
begin
minlen:=32;
maxlen:=0;
for i:=0 to alphasize-1 do
begin
if len[t,i]>maxlen then
maxlen:=len[t,i];
if len[t,i]<minlen then
minlen:=len[t,i];
end;
hb_create_decode_tables(limit[t],base[t],perm[t],len[t],
minlen,maxlen,alphasize);
minlens[t]:=minlen;
end;
end;
procedure Tbzip2_decode_stream.init_mtf;
var i,j:byte;
k:cardinal;
begin
k:=mtfa_size-1;
for i:=256 div mtfl_size-1 downto 0 do
begin
for j:=mtfl_size-1 downto 0 do
begin
mtfa[k]:=i*mtfl_size+j;
dec(k);
end;
mtfbase[i]:=k+1;
end;
end;
function Tbzip2_decode_stream.get_mtf_value:cardinal;
var zn:byte;
zvec:cardinal;
begin
if group_pos=0 then
begin
inc(group_no);
group_pos:=group_size;
gsel:=selector[group_no];
gminlen:=minlens[gsel];
glimit:=@limit[gsel];
gperm:=@perm[gsel];
gbase:=@base[gsel];
end;
dec(group_pos);
zn:=gminlen;
zvec:=get_bits(zn);
while zvec>glimit^[zn] do
begin
inc(zn);
zvec:=zvec shl 1 or byte(get_boolean);
end;
get_mtf_value:=gperm^[zvec-gbase^[zn]];
end;
procedure Tbzip2_decode_stream.move_mtf_block;
var i:byte;
j,k:cardinal;
begin
k:=MTFA_SIZE;
for i:=256 div MTFL_SIZE-1 downto 0 do
begin
j:=mtfbase[i];
Pcardinal(@mtfa[k- 4])^:=Pcardinal(@mtfa[j+12])^;
Pcardinal(@mtfa[k- 8])^:=Pcardinal(@mtfa[j+ 8])^;
Pcardinal(@mtfa[k-12])^:=Pcardinal(@mtfa[j+ 4])^;
dec(k,16);
Pcardinal(@mtfa[k ])^:=Pcardinal(@mtfa[j ])^;
mtfbase[i]:=k;
end;
end;
procedure Tbzip2_decode_stream.receive_mtf_values;
const run_a=0;
run_b=1;
var t,next_sym:cardinal;
es:cardinal;
n:byte;
nn,i:cardinal;
p,q:Pbyte;
u,v:Pcardinal;
lno,off:cardinal;
begin
group_no:=high(group_no);
group_pos:=0;
t:=0;
for i:=0 to 257 do
cftab[i]:=0;
init_mtf;
next_sym:=get_mtf_value;
while next_sym<>inuse_count+1 do
begin
{ writeln(t,' ',next_sym);
if t=22296 then
t:=t; }
if next_sym<=run_b then
begin
es:=0;
n:=0;
repeat
inc(es,(next_sym+1) shl n);
inc(n);
next_sym:=get_mtf_value;
until next_sym>run_b;
n:=seq_to_unseq[mtfa[mtfbase[0]]];
inc(cftab[n],es);
if t+es>100000*blocksize then
begin
error(streaderror,bzip2_data_error);
exit;
end;
while es>0 do
begin
tt^[t]:=n;
dec(es);
inc(t);
end;
end
else
begin
nn:=next_sym-1;
if nn<mtfl_size then
begin
{Avoid the costs of the general case.}
p:=@mtfa[mtfbase[0]];
q:=p+nn;
n:=q^;
repeat
q^:=(q-1)^;
dec(q);
until q=p;
q^:=n;
end
else
begin
{General case.}
lno:=nn div MTFL_SIZE;
off:=nn and (MTFL_SIZE-1);
p:=@mtfa[mtfbase[lno]];
q:=p+off;
n:=q^;
while(q<>p) do
begin
q^:=(q-1)^;
dec(q);
end;
u:=@mtfbase;
v:=u+lno;
repeat
mtfa[v^]:=mtfa[(v-1)^+MTFL_SIZE-1];
dec(v);
dec(v^);
until v=u;
mtfa[v^]:=n;
if v^=0 then
move_mtf_block;
end;
inc(cftab[seq_to_unseq[n]]);
tt^[t]:=cardinal(seq_to_unseq[n]);
inc(t);
if t>100000*blocksize then
begin
error(streaderror,bzip2_data_error);
exit;
end;
next_sym:=get_mtf_value;
end;
end;
tt_count:=t;
{Setup cftab to facilitate generation of T^(-1).}
t:=0;
for i:=0 to 256 do
begin
nn:=cftab[i];
cftab[i]:=t;
{ writeln(i,' ',t);}
inc(t,nn);
end;
end;
{$ifndef HAVE_DETRANSFORM}
procedure Tbzip2_decode_stream.detransform;
var a:cardinal;
p,q,r:Pcardinal;
begin
a:=0;
p:=@tt^[0];
q:=p+tt_count;
while p<>q do
begin
r:=@tt^[cftab[p^ and $ff]];
inc(cftab[p^ and $ff]);
r^:=r^ or a;
inc(a,256);
inc(p);
end;
end;
{$endif}
function Tbzip2_decode_stream.decode_block:boolean;
{Decode a new compressed block.}
var magic:array[1..6] of char;
stored_blockcrc:cardinal;
i:byte;
begin
for i:=1 to 6 do
magic[i]:=char(get_byte);
if magic='1AY&SY' then
begin
inc(current_block);
{ writeln('Block ',current_block,': Header ok');}
stored_blockcrc:=get_cardinal;
block_randomized:=get_boolean;
block_origin:=get_cardinal24;
{Receive the mapping table.}
receive_mapping_table;
alphasize:=cardinal(inuse_count)+2;
{ writeln('Mapping table ok.');}
{Receive the selectors.}
receive_selectors;
if status<>0 then
exit;
{ writeln('Selectors ok.');}
{Undo the MTF values for the selectors.}
undo_mtf_values;
{ writeln('Undo mtf ok.');}
{Receive the coding tables.}
receive_coding_tables;
if status<>0 then
exit;
{ writeln('Coding tables ok');}
{Build the Huffman tables.}
make_hufftab;
{ writeln('Huffman ok.');}
{Receive the MTF values.}
receive_mtf_values;
{ writeln('MTF OK');}
{Undo the Burrows Wheeler transformation.}
detransform;
{ writeln('Detransform OK');}
decode_available:=tt_count;
end
else
begin
if magic<>#$17'rE8P'#$90 then
error(streaderror,bzip2_bad_block_magic);
decode_block:=false;
end;
end;
procedure Tbzip2_decode_stream.new_block;
begin
if decode_block then
nextrle:=@tt^[tt^[block_origin] shr 8]
else
begin
error(streaderror,bzip2_endoffile);
nextrle:=nil;
end;
end;
procedure Tbzip2_decode_stream.consume_rle;inline;
{Make nextrle point to the next decoded byte. If nextrle did point to the last
byte in the current block, decode the next block.}
begin
{ Pcardinal(nextrle)^:=Pcardinal(nextrle)^ shr 8;}
nextrle:=@tt^[Pcardinal(nextrle)^ shr 8];
dec(decode_available);
if decode_available=0 then
new_block;
end;
procedure Tbzip2_decode_stream.rle_read(bufptr:Pbyte;var count:Longint);
var rle_len:cardinal;
data:byte;
label rle_write;
begin
rle_len:=rle_run_left;
data:=rle_run_data;
if block_randomized then
{Not yet implemented.}
runerror(212)
else
begin
if rle_len<>0 then
{Speed is important. Instead of an if statement within the
repeat loop use a goto outside the loop.}
goto rle_write;
repeat
if decode_available=0 then
break;
rle_len:=1;
data:=nextrle^;
consume_rle;
if (decode_available>0) and (data=nextrle^) then
begin
inc(rle_len);
consume_rle;
if (decode_available>0) and (data=nextrle^) then
begin
inc(rle_len);
consume_rle;
if (decode_available>0) and (data=nextrle^) then
begin
consume_rle;
inc(rle_len,nextrle^+1);
consume_rle;
end;
end;
end;
rle_write:
repeat
bufptr^:=data;
inc(bufptr);
dec(count);
dec(rle_len);
until (rle_len=0) or (count=0);
until count=0;
short:=count;
end;
rle_run_data:=data;
rle_run_left:=rle_len;
end;
procedure Tbzip2_decode_stream.read(var buf;count:Longint);
var bufptr:Pbyte;
begin
short:=0;
bufptr:=@buf;
if decode_available=high(decode_available) then
begin
{Initialize the rle process:
- Decode a block
- Initialize pointer.}
if not decode_block then
begin
error(streaderror,bzip2_endoffile);
nextrle:=nil;
end;
nextrle:=@tt^[tt^[block_origin] shr 8];
end;
rle_read(bufptr,count);
end;
destructor Tbzip2_decode_stream.done;
begin
if tt<>nil then
freemem(tt,blocksize*100000*sizeof(cardinal));
inherited done;
end;
end.