Mercurial > hg > dml-open-cliopatria
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| author | Daniel Wolff |
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| date | Tue, 09 Feb 2016 21:05:06 +0100 |
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/* Part of DML (Digital Music Laboratory) Copyright 2014-2015 Samer Abdallah, University of London This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this library; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ :- module(compression, [ with_transducer/3 , stream_length/1 , print_delimited_dcg/1 , complexity_method/1 , complexity/3 , conditional_complexity/4 , min_complexity/3 , min_conditional_complexity/4 , ncd/4 , conditional_ncd/5 , write_bytes/1 , length_prob/3 , with_stream_encoding/3 , with_zlib_stream/1 , zsync//1 ]). /** <module> Tools for applying compression programs to abitrary streams. This module provides a framework for applying a range of compression and delta compression programs to arbitrary streams generated by Prolog code. In particular, the predicates complexity/3 and conditional_complexity/4 use compression programs to estimate Kolmogorov complexity and conditional complexity. Compression programs are invoked by a collection of shell scripts included with this software, in the scripts/compression subdirectory of the dml cpack. The method to be used is determined by a term of type compression_method: == compression_method ---> id % no compression ; compress(c_method) ; diff(d_method,pred). c_method ---> lzma ; gz ; bz. d_method ---> bsdiff ; xdelta % using xdelta3 program ; vcdiff % using open-vcdiff ; vczip % using vczip tools from AT&T ; xdiff % using binary to text encoding and diff ; zzd(c_method, d_method) ; zzcd(c_method, d_method) ; dz(d_method, c_method). == Currently we do not subtract an known overheads associated with redundant information in compression program outputs, such as 'magic bytes' in a header used to enable tools to recognise which program was used to compress a given file. */ :- use_module(library(settings)). :- use_module(library(memo)). :- use_module(library(process)). :- use_module(library(fileutils)). :- use_module(library(swipe)). :- use_module(library(dcg_core)). :- use_module(library(dcg_codes)). :- use_module(library(zlib)). user:file_search_path(compression,dml(scripts/compression)). :- initialization time(memo_attach(memo(compression),[])). %% print_delimited_dcg(+P:phrase(list(code))) is det. % % Runs the DCG phrase to generate a list of character codes, and then % print the textually encoded length of the resulting list, followed by % a carriage return, followed by the characters themselves. Thus, the resulting % sequence of bytes is self-delimiting. print_delimited_dcg(Phrase) :- phrase(Phrase,Codes), length(Codes,Length), format('~d\n~s',[Length,Codes]). :- meta_predicate complexity(+,0,-), min_complexity(-,0,-), conditional_complexity(+,0,0,-), min_conditional_complexity(-,0,0,-), conditional_ncd(+,0,0,0,-), ncd(+,0,0,-). :- meta_predicate with_zlib_stream(//). %% complexity(+Method:compression_method, +Writer:pred, -K:nonneg) is det. %% complexity(-Method:compression_method, +Writer:pred, -K:nonneg) is nondet. %% complexity(-Method:compression_method, -Writer:pred, -K:nonneg) is nondet. % % Estimates the Kolmogorov complexity in bits of the sequence of bytes written to the % current output stream by the goal Writer. If Writer is unbound on entry, then % browses the set of previously computed results, which are stored in a volatile memo. % % Method can be =|id|= for no compression, or =|compress(M)|= for compression using % program M. If Method is a ground term of the form =|diff(M,RefWriter)|=, then % complexity is estimated using a delta compression with respect to the bytes written % by RefWriter. Methods are described in the module header. Conditional complexity % can more conveniently be estimated using conditional_complexity/4. complexity(Method,Mod:Writer,K) :- ( nonvar(Writer), complexity_method(Method), ground(Method) *->complexity1(Method,Mod:Writer,K) ; browse(complexity1(Method,Mod:Writer,K)) ). execable(A) :- var(A), !, fail. execable((A,B)) :- !, execable(A), execable(B). execable(_). :- volatile_memo min_complexity(-ground,+callable,-number). min_complexity(Best,Writer,KMin) :- aggregate(min(K,Meth),complexity(Meth,Writer,K),min(KMin,Best)). %% conditional_complexity(+M:cc_method, +RefWriter:pred, +Writer:pred, -K:nonneg) is det. % % Estimate conditional Kolmogorov complexity of byte sequence produced by Writer % given bit sequence produced by RefWriter, using one of several methods: % == % cc_method ---> id % no compression, complexity is length of data from Writer % ; compress(c_method) % ignore reference sequence and compress % ; delta(d_method) % do delta compression using given method % ; naive(c_method). % use naive estimate using concatentation method % == % The naive estimate of K(x|y) is C(yx) - C(y), where C(.) is compressed length and % xy is simply x concatenated with y. It may give nonsensical zero results. % It is not the length of any concrete message that can produce x given y. conditional_complexity(Method,Ref,Writer,K) :- ( Method=delta(Diff), M=diff(Diff,Ref) % ; Method=compress(C), M=compress(C) % ; Method=compress(zlib), M=zlib ; Method=delta(zlib), M=zlib(Ref) ; Method=delta(dlzma), M=dlzma(Ref) % ; Method=id, M=id ), complexity(M,Writer,K). conditional_complexity(naive(C),Ref,Writer,K) :- complexity(compress(C),Ref,KY), complexity(compress(C),(Ref,Writer),KXY), K is KXY - KY. ncd(naive(C),Writer1,Writer2,D) :- complexity(compress(C),Writer1,K1), complexity(compress(C),Writer2,K2), complexity(compress(C),(Writer1,Writer2),K12), D is (K12 - min(K1,K2))/max(K1,K2). ncd(CM-DM,Writer1,Writer2,D) :- complexity(CM,Writer1,K1), complexity(CM,Writer2,K2), conditional_complexity(DM,Writer1,Writer2,K2g1), conditional_complexity(DM,Writer2,Writer1,K1g2), D is max(min(K1,K1g2)/K1, min(K2,K2g1)/K2). ncd(opt,Writer1,Writer2,D) :- min_complexity(_,Writer1,K1), min_complexity(_,Writer2,K2), min_conditional_complexity(_,Writer1,Writer2,K2g1), min_conditional_complexity(_,Writer2,Writer1,K1g2), D is max(min(K1,K1g2)/K1, min(K2,K2g1)/K2). conditional_ncd(naive(Method),Ref,Writer1,Writer2,D) :- conditional_complexity(Method,Ref,Writer1,K1), conditional_complexity(Method,Ref,Writer2,K2), conditional_complexity(Method,Ref,(Writer1,Writer2),K12), D is (K12 - min(K1,K2))/max(K1,K2). conditional_ncd(DM,Ref,Writer1,Writer2,D) :- conditional_complexity(DM,Ref,Writer1,K1), conditional_complexity(DM,Ref,Writer2,K2), conditional_complexity(DM,(Ref,Writer1),Writer2,K2g1), conditional_complexity(DM,(Ref,Writer2),Writer1,K1g2), D is max(min(K1,K1g2)/K1, min(K2,K2g1)/K2). :- volatile_memo min_conditional_complexity(-ground,+callable,+callable,-number). min_conditional_complexity(Best,Ref,Writer,KMin) :- aggregate(min(K,Meth),(conditional_complexity(Meth,Ref,Writer,K),Meth\=naive(_)), min(KMin,Best)). %% complexity_method(-M:compression_method) is nondet. complexity_method(diff(Diff,_)) :- command(diff0(Diff,library('swipe.pl')),_,_). complexity_method(compress(Comp)) :- command(compress(Comp),_,_). complexity_method(id). complexity_method(zlib). complexity_method(zlibi). complexity_method(zlib(_)). complexity_method(dlzma(_)). :- persistent_memo complexity1(+ground,+callable,-number). complexity1(id,Writer,K) :- with_transducer(cat,Writer,stream_length(K)). complexity1(compress(Meth),Writer,K) :- with_transducer(compress(Meth), Writer, stream_length(K)). complexity1(diff(Diff,RefWriter),Writer,K) :- with_temp_files([F1], ( with_output_to_file(F1,RefWriter), with_transducer(diff0(Diff,F1), Writer, stream_length(K)))). complexity1(zlib,Writer,K) :- with_zlib_stream(call_zsync(Writer,K)). complexity1(zlibi,Writer,K) :- with_zlib_stream((call_zsync(write_bytes([255]),_), call_zsync(Writer,K))). complexity1(zlib(Ref),Writer,K) :- with_zlib_stream((call_zsync(Ref,_), call_zsync(Writer,K))). complexity1(dlzma(RefWriter),Writer,K) :- with_temp_files([F1], ( with_output_to_file(F1,RefWriter), with_transducer(dlzma(F1,['-b0']), Writer, read_line_to_string(current_input,KString)))), number_string(K,KString). subs(_,_,T1,T2) :- var(T1), !, T1=T2. subs(Old,New,T1,T2) :- T1==Old, !, T2=New. subs(Old,New,T1,T2) :- T1 =.. [F | Args1], maplist(subs(Old,New),Args1,Args2), T2 =.. [F | Args2]. % this is hopeless... length_prob(Meth,L,Prob) :- length(X,L), aggregate( sum(2**(-8*B)), X^(maplist(between(0,255),X), with_transducer(compress(Meth), write_bytes(X), stream_length(B)), format(user_error, '\r~w : ~w', [X,B]) ), Prob). %% write_bytes(+Bytes:list(between(0,255))) is det. % Writes a sequence of bytes to current_output. write_bytes(Bytes) :- with_stream_encoding(current_output,octet,maplist(put_code,Bytes)). % -------------------------------- Using ZLIB ------------------------------ with_zlib_stream(Phrase) :- setup_call_cleanup( open_null_stream(Out), setup_call_cleanup( zopen(Out,ZOut,[level(9),close_parent(false)]), with_output_to(ZOut,call_dcg(Phrase,Out-0,_)), close(ZOut)), close(Out)). zpos(Pos,Out-Pos,Out-Pos). zsync(Bits,Out-Pos0,Out-Pos1) :- flush_output, byte_count(Out,Pos1), ( Pos1=Pos0 -> Bits=0 % no data since last sync ; Bits is 8*((Pos1-Pos0)-4)-(3+3) % subtract estimate of final type 0 block. ). call_zsync(Goal,Delta) --> {call(Goal)}, zsync(Delta). % ------ Method comparison ----- evaluate_delta(KRel,Method) :- call_with_mode(browse, setof(K-Meth,conditional_complexity(Meth,_:_,_:_,K),KMeths)), memberchk(_-delta(_),KMeths), exclude(eval_exclude,KMeths,KMeths1), KMeths1 = [KBest-_|_], member(K-Method,KMeths1), KRel is K/KBest. :- public method_rankings/2. method_rankings(Method,Scores) :- setof( Method-KRels, bagof(KRel, evaluate_delta(KRel,Method), KRels), AllScores), member(Method-Scores,AllScores). eval_exclude(_-Method) :- exclude_method(Method). exclude_method(naive(_)). exclude_method(delta(DMethod)) :- exclude_dmethod(DMethod). exclude_dmethod(xdiff). exclude_dmethod(dz(DM,_)) :- exclude_dmethod(DM). exclude_dmethod(zzcd(_,DM)) :- exclude_dmethod(DM). exclude_dmethod(zzd(_,DM)) :- exclude_dmethod(DM). delta_method(compress(C),compress(C)). delta_method(delta(M),delta(M)). delta_method(id,id). % ----------------------- Compression framework -------------------------------------- swipe:def(Pipe,Def) :- def(Pipe,Def). def( findcat(Dir), sh(0 >> $_, '~s ~s',[compression(findcat)+execute, file(Dir,[file_type(directory)])])). def( humdump(Dir), findcat(Dir) >> sh($hum >> $hum,'rid -G')). def( length, sh($_ >> $number, 'wc -c')). def( prepend(File^T), sh($T >> $T,'cat ~s -',[File+read])). def( prepend(_<Pipe), Pipe * cat). % sh($T >> $T,'cat ~s -',[T<Pipe])). def( unprepend(File^T), sh($T >> $T, 'tail -c +$((1+~s))',[$(File^T :> length)])). def( unprepend(T<Pipe), sh($T >> $T, 'tail -c +$((1+~s))',[$(Pipe >> length)])). def( compress(Method), sh( $X >> $z(Method,X), Cmd)) :- compressor(Method,Cmd,_). def( decompress(Method), sh( $z(Method,X) >> $X, Cmd)) :- compressor(Method,_,Cmd). def( diff0(Diff,Ref), diff(Diff,Ref)). % def( diff0(dz(Diff,Comp),Ref), diff(Diff,Ref) >> compress(Comp)). def( diff(Diff,Ref), diff(Diff, encode, Ref+read)). % def( diff(zzd(Comp,Diff),Ref), compress(Comp) >> buf(2,diff(Diff, encode, T<(Ref^T :> compress(Comp))))). def( diff(zzcd(Comp,Diff),Ref), prepend(Ref^T) >> compress(Comp) >> buf(2,diff(Diff, encode, _<(Ref^T :> compress(Comp))))). def( patch(Method,Ref), diff(Method, decode, Ref+read)). def( patch(zzd(Comp,Diff),Ref), buf(2,diff(Diff, decode, _<(Ref^_ :> compress(Comp)))) >> decompress(Comp)). def( patch(zzcd(Comp,Diff),Ref), buf(2,diff(Diff, decode, _<(Ref^T :> compress(Comp)))) >> decompress(Comp) >> unprepend(Ref^T)). def( diff(Method,encode,RefSource), sh( $X >> $dz(Method,X), [compression(Script)+execute, encode, RefSource | Args])) :- differ(Method,Script,Args,_). def( diff(Method,decode,RefSource), sh( $dz(Method,X) >> $X, [compression(Script)+execute, decode, RefSource | Args])) :- differ(Method,Script,_,Args), Method\=zvcz. def( buf(N,Pipe), sh(Type,'~s ~d ~s',[compression(bufs)+execute, \N, \Cmd])) :- command(Pipe,Type,Cmd). def( diff1(Diff,Ref), diff2(Diff, Ref)). def( diff1(zzd(Comp,Diff),Ref), compress(Comp) >> diff2(Diff, Ref >> compress(Comp))). def( diff1(zzcd(Comp,Diff),Ref), prepend(_<Ref) >> compress(Comp) >> diff2(Diff, Ref >> compress(Comp))). def( patch1(Diff,Ref), patch2(Diff, Ref)). def( patch1(zzd(Comp,Diff),Ref), patch2(Diff, Ref >> compress(Comp)) >> decompress(Comp)). def( patch1(zzcd(Comp,Diff),Ref), patch2(Diff, Ref >> compress(Comp)) >> decompress(Comp) >> unprepend(_<Ref)). def( diff2(Method,Ref), sh( $X >> $dz(Method,X), [compression(encode)+execute, Script, X<Ref | Args])) :- differ(Method,Script,Args,_). def( patch2(Method,Ref), sh( $dz(Method,X) >> $X, [compression(decode)+execute, Script, X<Ref | Args])) :- differ(Method,Script,_,Args), Method\=zvcz. def( dlzma(Ref,Opts), sh($X >> $dz(dlzma,X), [compression(dlzma)+execute | Args])) :- append(Opts,[Ref],Args). % compressor(xz,xz,xzcat). compressor(lzma,lzma,lzcat). compressor(xzraw,'xz -q -F raw','xzcat -F raw'). compressor(gz,gzip,zcat). compressor(bz,bzip2,bzcat). contains(Diff,Diff). contains(dz(D1,_),D2) :- contains(D1,D2). contains(zzd(_,D1),D2) :- contains(D1,D2). contains(zzcd(_,D1),D2) :- contains(D1,D2). % :- setting(max_vczip_chain_length, nonneg, 2, 'Maximum length of vczip processing chain'). differ(Method,Exec,[],[]) :- differ(Method,Exec). differ(Method-Opts, Exec, EncArgs, []) :- differ(Method,Exec), options_for(Method,Opts,EncArgs). differ(vczip(vcdiff),zvcz,['-Vcdiff'],[]). differ(vczip(delta),zvcz,['-mdelta'],[]). differ(vczip(sieve),zvcz,['-msieve.delta'],[]). % differ(vczip(Delta,Chain,Encode),zvcz,[\Codes],[]) :- % setting(max_vczip_chain_length,N), % between(1,N,L), % length(Chain,L), % vczip_chain(Delta,Chain,Encode,Codes,[]). % differ(bsdiff,zbs). % differ(xdelta,zxd). differ(vcdiff,zvcd). % differ(vczip,zvcz). % differ(xdiff,zdiff). options_for(Method,Opts,Args) :- Opts=[_|_], setof(opt(Opt,Gen,A1,A2),method_option(Method,Opt,Gen,A1,A2),Possible), seqmap(maybe_option,Possible,Opts-Args,[]-[]). maybe_option(_) --> []. maybe_option(opt(Opt,Gen,A1,A2),[Opt|Opts]-A1,Opts-A2) :- call(Gen). method_option(xdelta, secondary(A), member(A,[djw,fgk])) --> ['-S',A]. method_option(vcdiff, target_matches, true) --> ['-target_matches']. % vczip_chain(Delta,Chain,Encode) --> % "-m", % vczip_delta(Delta), ",", % seqmap_with_sep(",",vczip_transform,Chain), ",", % vczip_encode(Encode). % vczip_delta(delta) --> "delta". % vczip_delta(sieve) --> "sieve.delta". % vczip_transform(bwt) --> "bwt". % vczip_transform(mtf) --> "mtf". % vczip_transform(rle) --> "rle". % vczip_transform(rle(N)) --> "rle.", {between(0,1,N)}, at(N). % vczip_encode(huffman) --> "huffman". % vczip_encode(huffgroup) --> "huffgroup". % vczip_encode(huffpart) --> "huffpart". compressor_overhead(gz,18). % see http://www.onicos.com/staff/iz/formats/gzip.html, https://tools.ietf.org/html/rfc1952 compressor_overhead(bz,4). % http://en.wikipedia.org/wiki/Bzip2 (need to know number of blocks for better estimate) compressor_overhead(lzma,0). % http://svn.python.org/projects/external/xz-5.0.3/doc/lzma-file-format.txt % ------------------------- Pipe and file tools ---------------------------------- splice_in(Pipe) :- with_pipe_input(S,Pipe,copy_stream_data(current_input,S)). splice_out(Pipe) :- with_pipe_output(S,Pipe, ( with_stream_encoding(S,octet, with_stream_encoding(current_output,octet, copy_stream_data(S,current_output))))). :- op(1050,xfy,&). %% with_transducer(+P:pipe, +Writer:pred, +Reader:pred) is det. % Runs a pipeline defined using the framework provided by library(swipe), % while concurrently sending data written by Writer to the process % on its standard input and making data from the standard output of the % process available to Reader on current_input. :- meta_predicate with_transducer(+,0,0). with_transducer(Pipe,Writer,Reader) :- with_pipe_io( To-From, Pipe, ( call_cleanup(with_output_to(To,Writer), close(To)) & call_cleanup(with_input_from(From,Reader), close(From)) )). A & B :- concurrent(2, [A,B], []). %% with_stream_encoding(+S:stream,+E:encoding,+G:pred) is det. % Call goall G with encoding of stream S temporarily set to E. Encoding % is restored afterwards. :- meta_predicate with_stream_encoding(+,+,0). with_stream_encoding(S,Enc,Goal) :- stream_property(S,encoding(Old)), setup_call_cleanup(set_stream(S,encoding(Enc)), Goal, set_stream(S,encoding(Old))). %% stream_length(-L:natural) is det. % Reads all the data available on Prolog stream current_input and returns the % number of bits consumed. stream_length(S,Bits) :- with_input_from(S,stream_length(Bits)). stream_length(Bits) :- with_stream_encoding(current_input,octet,accum_length(0,Bytes)), Bits is 8*Bytes. accum_length(L,L) :- at_end_of_stream, !. accum_length(L1,L3) :- read_pending_input(current_input, Codes, []), length(Codes,L), L2 is L1 + L, accum_length(L2,L3). with_temp_files(Files,Goal) :- must_be(list(var),Files), setup_call_cleanup( maplist(tmp_file_stream(binary),Files,Streams), (maplist(close,Streams), call(Goal)), maplist(delete_file,Files)).