%% Oh Emacs, this is a -*- Makefile -*-, so give me tabs. \documentclass{article} \usepackage{axiom} \title{\$SPAD/src/algebra Makefile} \author{Timothy Daly \and Gabriel Dos~Reis} \begin{document} \maketitle \begin{abstract} \end{abstract} \eject \tableofcontents \eject \section{Adding new algebra} This is a complex process by its very nature. Developers and Maintainers who undertake the process need to understand quite a lot of detail. The ultimate steps to add algebra are tedious but simple. Note that only algebra code that gets shipped with the system needs to undergo this process. User code can be compiled once the distributed algebra exists and does not need either this Makefile or this installation process. NOTE: If you add new algebra to this file you must also update \File{src/algebra/exposed.lsp.pamphlet} otherwise the new algebra won't be loaded by the interpreter when needed. Since understanding is the key to making correct changes to this file I'll work on explaining the details of why things need to exist. The first idea that you need to understand is the overall process of adding algebra code. Lets assume that you have a brand new spad file, called \File{foo.spad} containing a simple domain [[BAR]]. The steps in the process of adding this file are: \begin{enumerate} \item Find out where the algebra code lives in the lattice. You do this by \begin{enumerate} \item starting a new interpsys session \item collecting all the names of the algebra files BAR requires \item determining which layer each of the required files resides \item determine the highest layer (e.g. 14) that contains the required files \end{enumerate} \item insert the documentation into the next layer (e.g. 15) \item insert the [[\${OUT}/BAR.$(FASLEXT)]] file into the layer's file list \end{enumerate} \section{Rebuilding the algebra from scratch} Compile order is important. Here we try to define the ordered lattice of spad file dependencies. However this is, in reality, a graph rather than a lattice. In order to break cycles in this graph we explicitly cache a few of the intermediate generated lisp code for certain files. These are marked throughout (both here and in the various pamphlet files) with the word {\bf BOOTSTRAP}. If we take a cycle such as [[RING]] we discover that in order to compile the spad code we must load the compiled definition of [[RING]]. In this case we must compile the cached lisp code before we try to compile the spad file. It is highly recommended that you try to become a developer of Axiom and read the archived mailing lists before you decide to change a cached file. In the fullness of time we will rewrite the whole algebra structure into a proper lattice if possible. Alternatively we'll reimplement the compiler to handle graphs. Or deeply adopt the extensible domains. Whatever we do will be much discussed (and cause much disgust) around the campfire. If you come up with a brilliant plan that gets adopted we'll even inscribe your name on a log and add it to the fire. In the code that follows we find the categories, packages and domains that compile with no dependencies and call this set ``layer 0''. Next we find the categories, packages and domains that will compile using only ``layer 0'' code and call this ``layer 1''. We walk up the lattice in this fashion adding layers. Note that at layer 3 this process runs into cycles and we create the ``layer 3 bootstrap'' stanzas before continuing upward. \section{The Algebra Lattice Layers} \subsection{Layer 0 Bootstrap} \subsubsection{Completed spad files} \begin{verbatim} si.spad.pamphlet (INS SINT) \end{verbatim} Note well that none of the algebra stanzas should include these files in the preconditions otherwise we have an infinite compile loop. These files are originally bootstrapped from lisp code when we build the system for the first time but they are forcibly recompiled at the end of the build so they reflect current code (just in case someone changes the spad code but does not re-cache the generated lisp). If you add these files as preconditions (note that they are all in the \File{strap/} directory rather than the {\bf OUT} directory like everything else) then the final recompile will invalidate all of the rest of the algebra targets which will get rebuilt again causing these targets to be out of date. The rest of the loop is left up to the student. The bootstrap process works because first we ask for the compiled lisp code stanzas (the \File{strap/BAR.$(FASLEXT)} files), THEN we ask for the final algebra code stanzas (the [[\${OUT}/BAR.$(FASLEXT)]] files). This is a very subtle point so think it through carefully. Notice that this is the only layer calling for \File{strap/} files. All other layers call for [[\${OUT}]] files. If you break this the world will no longer compile so don't change it if you don't understand it. \begin{verbatim} LAYER0BOOTSTRAP=${OUT}/XPR.$(FASLEXT) \end{verbatim} <>= # The list of objects necessary to bootstrap the whole algebra library. axiom_algebra_layer_strap = \ $(addprefix strap/,$(axiom_algebra_bootstrap)) axiom_algebra_layer_strap_objects = \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_strap)) @ <>= axiom_algebra_bootstrap = \ ABELGRP ABELGRP- ABELMON ABELMON- \ ABELSG ABELSG- ALAGG BOOLEAN \ CABMON CHAR CLAGG CLAGG- \ COMRING DFLOAT DIFRING DIFRING- \ DIVRING DIVRING- ENTIRER ES \ ES- EUCDOM EUCDOM- FFIELDC \ FFIELDC- FPS FPS- GCDDOM \ GCDDOM- HOAGG HOAGG- ILIST \ INS INS- INT INTDOM \ INTDOM- ISTRING LIST LNAGG \ LNAGG- LSAGG LSAGG- MONOID \ MONOID- MTSCAT NNI OINTDOM \ ORDRING ORDRING- OUTFORM PI \ PRIMARR POLYCAT POLYCAT- PSETCAT \ PSETCAT- QFCAT QFCAT- RCAGG \ RCAGG- REF RING RING- \ RNG RNS RNS- SETAGG \ SETAGG- SINT \ STAGG STAGG- SYMBOL TSETCAT \ TSETCAT- UFD UFD- ULSCAT \ UPOLYC UPOLYC- URAGG URAGG- \ VECTOR axiom_algebra_bootstrap_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_bootstrap)) axiom_algebra_bootstrap_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT), $(axiom_algebra_bootstrap))) @ \subsection{Layer 0} <>= $(OUT)/UTYPE.$(FASLEXT): $(OUT)/TYPE.$(FASLEXT) $(OUT)/AHYP.$(FASLEXT): $(OUT)/TYPE.$(FASLEXT) $(OUT)/PRIMCAT.$(FASLEXT): $(OUT)/TYPE.$(FASLEXT) $(OUT)/ATTREG.$(FASLEXT): $(OUT)/TYPE.$(FASLEXT) $(OUT)/CONDUIT.$(FASLEXT): $(OUT)/TYPE.$(FASLEXT) $(OUT)/CFCAT.$(FASLEXT): $(OUT)/TYPE.$(FASLEXT) $(OUT)/ELTAB.$(FASLEXT): $(OUT)/TYPE.$(FASLEXT) $(OUT)/MSYSCMD.$(FASLEXT): $(OUT)/TYPE.$(FASLEXT) $(OUT)/KOERCE.$(FASLEXT): $(OUT)/TYPE.$(FASLEXT) $(OUT)/KRCFROM.$(FASLEXT): $(OUT)/TYPE.$(FASLEXT) $(OUT)/KONVERT.$(FASLEXT): $(OUT)/TYPE.$(FASLEXT) $(OUT)/KVTFROM.$(FASLEXT): $(OUT)/TYPE.$(FASLEXT) $(OUT)/BASTYPE.$(FASLEXT): $(OUT)/TYPE.$(FASLEXT) $(OUT)/SETCAT.$(FASLEXT) $(OUT)/SETCAT-.$(FASLEXT): $(OUT)/BASTYPE.$(FASLEXT) $(OUT)/FINITE.$(FASLEXT): $(OUT)/SETCAT.$(FASLEXT) $(OUT)/ORDSET.$(FASLEXT) $(OUT)/ORDSET-.$(FASLEXT): $(OUT)/SETCAT.$(FASLEXT) $(OUT)/FILECAT.$(FASLEXT): $(OUT)/SETCAT.$(FASLEXT) $(OUT)/SEXCAT.$(FASLEXT): $(OUT)/SETCAT.$(FASLEXT) $(OUT)/STEP.$(FASLEXT): $(OUT)/SETCAT.$(FASLEXT) $(OUT)/LMODULE.$(FASLEXT): $(OUT)/SETCAT.$(FASLEXT) $(OUT)/RMODULE.$(FASLEXT): $(OUT)/SETCAT.$(FASLEXT) $(OUT)/SGROUP.$(FASLEXT) $(OUT)/SGROUP-.$(FASLEXT): $(OUT)/SETCAT.$(FASLEXT) $(OUT)/ABELSG.$(FASLEXT) $(OUT)/ABELSG-.$(FASLEXT): $(OUT)/SETCAT.$(FASLEXT) $(OUT)/CTORKIND.$(FASLEXT): $(OUT)/SETCAT.$(FASLEXT) $(OUT)/IOMODE.$(FASLEXT): $(OUT)/SETCAT.$(FASLEXT) $(OUT)/PRINT.$(FASLEXT): $(OUT)/TYPE.$(FASLEXT) axiom_algebra_layer_0 = \ AHYP ATTREG CFCAT ELTAB KOERCE KONVERT \ KRCFROM KVTFROM \ MSYSCMD OM OMCONN OMDEV OUT \ PRIMCAT PRINT PTRANFN SPFCAT TYPE UTYPE \ PROPERTY BASTYPE BASTYPE- LMODULE \ RMODULE FINITE STEP SGROUP SGROUP- ABELSG \ ABELSG- ORDSET ORDSET- FILECAT SEXCAT \ MKBCFUNC MKRECORD MKUCFUNC DROPT1 PLOT1 ITFUN2 \ ITFUN3 STREAM1 STREAM2 STREAM3 ANY1 SEGBIND2 \ COMBOPC EQ2 NONE1 CONDUIT IOMODE CTORKIND axiom_algebra_layer_0_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_0)) axiom_algebra_layer_0_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_0))) @ \subsection{Layer 1} <>= $(OUT)/AGG.$(FASLEXT) $(OUT)/AGG-.$(FASLEXT): $(OUT)/TYPE.$(FASLEXT) $(OUT)/HOMOTOP.$(FASLEXT): $(OUT)/KOERCE.$(FASLEXT) $(OUT)/KRCFROM.$(FASLEXT) $(OUT)/ITUPLE.$(FASLEXT): $(OUT)/KOERCE.$(FASLEXT) $(OUT)/PATAB.$(FASLEXT): $(OUT)/KOERCE.$(FASLEXT) $(OUT)/PPCURVE.$(FASLEXT): $(OUT)/KOERCE.$(FASLEXT) $(OUT)/PSCURVE.$(FASLEXT): $(OUT)/KOERCE.$(FASLEXT) $(OUT)/IEVALAB.$(FASLEXT) $(OUT)/IEVALAB-.$(FASLEXT): \ $(OUT)/SETCAT.$(FASLEXT) $(OUT)/EVALAB.$(FASLEXT) $(OUT)/EVALAB-.$(FASLEXT): \ $(OUT)/IEVALAB.$(FASLEXT) $(OUT)/LOGIC.$(FASLEXT) $(OUT)/LOGIC-.$(FASLEXT): $(OUT)/BASTYPE.$(FASLEXT) $(OUT)/PROPLOG.$(FASLEXT): $(OUT)/SETCAT.$(FASLEXT) $(OUT)/RETRACT.$(FASLEXT) $(OUT)/RETRACT-.$(FASLEXT): $(OUT)/KRCFROM.$(FASLEXT) $(OUT)/MAYBE.$(FASLEXT): $(OUT)/KOERCE.$(FASLEXT) $(OUT)/RETRACT.$(FASLEXT) $(OUT)/BYTEORD.$(FASLEXT): $(OUT)/SETCAT.$(FASLEXT) axiom_algebra_layer_1 = \ AGG AGG- IEVALAB IEVALAB- FORTCAT ITUPLE \ PATAB PPCURVE PSCURVE REAL RESLATC RETRACT \ RETRACT- SEGCAT BINDING BMODULE LOGIC \ LOGIC- EVALAB EVALAB- FEVALAB FEVALAB- \ OSGROUP MAYBE DATAARY PROPLOG HOMOTOP BYTEORD axiom_algebra_layer_1_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_1)) axiom_algebra_layer_1_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_1))) @ \subsection{Layer 2} <>= axiom_algebra_layer_2 = \ ELTAGG ELTAGG- \ SYNTAX INTRET IXAGG IXAGG- SEGXCAT \ CONTOUR LIST3 MKFUNC OASGP KTVLOGIC FNCAT \ IDENT $(OUT)/ELTAGG.$(FASLEXT): $(OUT)/AGG.$(FASLEXT) $(OUT)/SETCAT.$(FASLEXT) $(OUT)/IXAGG.$(FASLEXT): $(OUT)/ELTAGG.$(FASLEXT) $(OUT)/SYNTAX.$(FASLEXT): $(OUT)/IDENT.$(FASLEXT) axiom_algebra_layer_2_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_2)) axiom_algebra_layer_2_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_2))) @ \subsection{Layer 3} <>= axiom_algebra_layer_3 = \ GRDEF SCOPE MAPHACK1 MAPHACK2 MAPHACK3 MAPPKG1 \ MAPPKG2 MAPPKG3 INTBIT MONAD MONAD- axiom_algebra_layer_3_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_3)) axiom_algebra_layer_3_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_3))) @ \subsubsection{Completed spad files} <>= axiom_algebra_layer_4 = \ ANON COMM COMPPROP ESCONT1 EXIT \ FAMONC FORMULA1 IDPC NONE NUMINT \ ODECAT OMENC ONECOMP2 OPTCAT \ PALETTE PARPCURV PARPC2 PARSCURV PARSC2 PARSURF \ PARSU2 PATMAB PATRES2 PATTERN1 PDECAT \ REPSQ REPDB RFDIST RIDIST SPACEC SPLNODE \ SUCH TEX1 UDVO YSTREAM PAIR ENV \ ATRIG ATRIG- GROUP GROUP- LALG LALG- \ OAMON BGAGG BGAGG- BRAGG BRAGG- ELAGG \ ELAGG- DLAGG MODULE MODULE- axiom_algebra_layer_4_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_4)) axiom_algebra_layer_4_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_4))) @ \subsection{Layer 5} <>= axiom_algebra_layer_5 = \ CACHSET CHARNZ CHARZ DVARCAT DVARCAT- ELEMFUN \ ELEMFUN- ESTOOLS2 FCOMP FPATMAB IDPAM IDPO \ INCRMAPS KERNEL2 LINEXP MODMONOM MONADWU MONADWU- \ MRF2 NARNG NARNG- NSUP2 ODVAR OPQUERY \ ORDFIN ORDMON PATMATCH PERMCAT PDRING PDRING- \ SDVAR SUP2 TRIGCAT TRIGCAT- ULS2 UP2 \ ELABEXPR OCAMON axiom_algebra_layer_5_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_5)) axiom_algebra_layer_5_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_5))) @ \subsection{Layer6} <>= $(OUT)/CHARPOL.$(FASLEXT): $(OUT)/SETCAT-.$(FASLEXT) axiom_algebra_layer_6 = \ ALGEBRA ALGEBRA- AUTOMOR CARTEN2 CHARPOL COMPLEX2 \ DIFEXT DIFEXT- ES1 ES2 GRMOD GRMOD- \ HYPCAT HYPCAT- MKCHSET MODRING NASRING NASRING- \ SORTPAK ZMOD PRQAGG QUAGG SKAGG DQAGG \ PID OAGROUP OAMONS BYTE SYSINT SYSNNI axiom_algebra_layer_6_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_6)) axiom_algebra_layer_6_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_6))) @ \subsection{Layer7} \begin{verbatim} \end{verbatim} <>= axiom_algebra_layer_7 = \ BTCAT BTCAT- LNAGG LNAGG- FMCAT IDPOAM \ IFAMON GRALG GRALG- FLAGG FLAGG- \ INT8 INT16 INT32 INT64 UINT8 UINT16 \ UINT32 UINT64 axiom_algebra_layer_7_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_7)) axiom_algebra_layer_7_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_7))) @ \subsection{Layer8} <>= axiom_algebra_layer_8 = \ BSTREE BTOURN CARD DRAWHACK FACTFUNC FMTC \ FR2 FRAC2 FRUTIL ITAYLOR MLO NAALG \ NAALG- OP ORDCOMP2 RANDSRC UNISEG2 XALG \ FIELD FIELD- A1AGG A1AGG- ARR2CAT ARR2CAT- axiom_algebra_layer_8_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_8)) axiom_algebra_layer_8_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_8))) @ \subsection{Layer9} <>= axiom_algebra_layer_9 = \ AMR AMR- DEGRED DLP EAB ESTOOLS1 \ FAGROUP FAMONOID FLINEXP FLINEXP- FRETRCT FRETRCT- \ FSERIES FT IDPAG IDPOAMS INFINITY LA \ OMLO ORTHPOL PRODUCT PADICCT PMPRED PMASS \ PTFUNC2 RADCAT RADCAT- RATRET RADUTIL UPXS2 \ XFALG ZLINDEP BBTREE LSAGG LSAGG- SRAGG \ SRAGG- STRICAT ODEIFTBL NIPROB ODEPROB OPTPROB \ PDEPROB COLOR SIG axiom_algebra_layer_9_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_9)) axiom_algebra_layer_9_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_9))) @ \subsection{Layer10} <>= axiom_algebra_layer_10 = \ BFUNCT BPADIC \ BTREE CRAPACK DEQUEUE DLIST \ DRAWCX D01GBFA D02EJFA D03FAFA \ DRAWPT FAMR FAMR- FLASORT \ FLAGG2 FGROUP FM FM1 \ FPC FPC- FMONOID INDE \ IPADIC IROOT IR2 LEXP \ LIECAT LIECAT- LIST2 LIST2MAP \ LMOPS LZSTAGG LZSTAGG- MAGMA \ MESH MOEBIUS MODFIELD MODOP \ MRING MTHING NCNTFRAC NCODIV \ NUMTUBE ODR OFMONOID ONECOMP \ ORDCOMP OREPCAT OREPCAT- OWP \ PADIC PATTERN2 PATLRES PARTPERM \ PBWLB PENDTREE PGE PGROEB \ PINTERP PLOTTOOL PFR PMDOWN \ PRTITION PMINS PMLSAGG PMTOOLS \ PSCAT PSCAT- QFORM QUEUE \ SCACHE SEG SEG2 SEXOF \ STACK STTAYLOR TABLBUMP TABLEAU \ TOPSP TRANFUN TRANFUN- TUBE \ UDPO UNISEG VIEW VSPACE \ VSPACE- XPOLYC XPR BTAGG BTAGG- \ FUNDESC axiom_algebra_layer_10_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_10)) axiom_algebra_layer_10_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_10))) @ \subsection{Layer11} <>= axiom_algebra_layer_11 = \ STRING \ APPLYORE ARRAY1 ARRAY12 ARRAY2 \ ASTACK COMBINAT \ CSTTOOLS D01FCFA E04MBFA FARRAY \ FLALG GALUTIL HEAP IARRAY1 \ IARRAY2 IFARRAY INTCAT INTHEORY \ IRREDFFX LFCAT LODOCAT LODOCAT- \ LWORD MATCAT MATCAT- MATSTOR \ ORESUP OREPCTO OREUP PLOT3D \ PR PREASSOC PRIMARR2 REDORDER \ STREAM SYMPOLY \ TS TUPLE UPSCAT UPSCAT- \ VECTCAT VECTCAT- XDPOLY XEXPPKG \ XF XF- XPBWPOLY XPOLY \ XRPOLY axiom_algebra_layer_11_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_11)) axiom_algebra_layer_11_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_11))) @ \subsection{Layer12} <>= axiom_algebra_layer_12 = \ DIOPS DIOPS- DIAGG DIAGG- BITS DIRPROD2 IMATRIX \ IVECTOR LPOLY LSMP LSMP1 MATCAT2 PTCAT TRIMAT \ FSAGG FSAGG- SYSTEM HOSTNAME PORTNUM axiom_algebra_layer_12_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_12)) axiom_algebra_layer_12_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_12))) @ \subsection{Layer13} <>= axiom_algebra_layer_13 = \ KDAGG KDAGG- \ ASSOCEQ CARTEN CLIF CLIP \ COORDSYS DBASE DHMATRIX DIOSP \ DIRPCAT DIRPCAT- D02BBFA D02BHFA \ D02CJFA FAXF FAXF- FFPOLY2 \ FNLA GRAY HB IRSN \ MCALCFN MHROWRED NUMODE NUMQUAD \ ODESYS ODETOOLS ORDFUNS PERMAN \ PFECAT PFECAT- POINT PSEUDLIN \ PTPACK REP2 SETMN SEX \ SYMFUNC VECTOR2 CHAR \ INBCON INBCON- OUTBCON OUTBCON- axiom_algebra_layer_13_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_13)) axiom_algebra_layer_13_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_13))) @ \subsection{Layer14} <>= axiom_algebra_layer_14 = \ TBAGG TBAGG- ALIST FS FS- ACF ACF- \ ACFS ACFS- BALFACT BEZOUT BINARY BINFILE BOUNDZRO \ BPADICRT BRILL CDEN CHVAR \ COMMUPC CONTFRAC CVMP CYCLOTOM \ CYCLES DDFACT DECIMAL DIRPROD DISPLAY DMP \ DPMO DPOLCAT DPOLCAT- D01AJFA \ D01AKFA D01ALFA D01AMFA D01APFA \ D01AQFA EMR EQ ERROR \ EVALCYC E04DGFA E04FDFA E04GCFA \ E04JAFA FACUTIL FF FFCG \ FFCGX FFHOM FFNB FFNBX \ FFPOLY FFX FFSLPE FGLMICPK \ FILE FINAALG FINAALG- FINRALG \ FINRALG- FLOATRP FNAME \ FOP FORMULA FORT FRAC \ FTEM GENEEZ GENMFACT GENPGCD \ GALFACTU GALPOLYU GB GBEUCLID \ GBF GBINTERN GHENSEL GMODPOL \ GOSPER GRIMAGE GROEBSOL HDMP \ HDP HEXADEC HEUGCD IBPTOOLS \ IFF IBITS ICARD ICDEN \ IDECOMP IIARRAY2 IMATLIN IMATQF \ INMODGCD INNMFACT INPSIGN INTHERTR \ INTRAT INTRF INTSLPE INTTR \ ISUMP LAUPOL LEADCDET LGROBP \ LIMITRF LINDEP LO LPEFRAC \ LSPP MATLIN MCDEN MDDFACT \ MFINFACT MFLOAT MINT MLIFT \ MMAP MODMON MONOTOOL MPCPF \ MPC2 MPC3 MPOLY MPRFF \ MRATFAC MULTSQFR NORMRETR NPCOEF \ NSUP NTPOLFN ODP ODEPRIM \ ODEPRRIC OMPKG OMSERVER PADEPAC \ PADICRAT PADICRC PCOMP PDECOMP \ PF PFBR PFBRU PFOTOOLS \ PFRPAC PGCD PINTERPA PLEQN \ PMPLCAT PMQFCAT PNTHEORY POLUTIL \ POLTOPOL POLYCATQ POLYLIFT POLYROOT \ POLY2 POLY2UP PRS PSQFR \ PUSHVAR QALGSET QFCAT2 RADIX \ RATFACT RCFIELD RCFIELD- RDETR \ RDETRS REAL0 REAL0Q REALSOLV \ RESRING RETSOL RF RFFACTOR \ RMATCAT RMATCAT- RRCC RRCC- \ SCPKG SHDP SHP SIGNRF \ SMITH SMP SMTS SOLVEFOR \ SPLTREE STINPROD STTFNC SUBRESP \ SUMRF SUP SUPFRACF TANEXP \ TEMUTL TEX TEXTFILE TREE \ TWOFACT UNIFACT UP UPCDEN \ UPDECOMP UPDIVP UPMP UPOLYC2 \ UPXSCAT UPSQFREE VIEWDEF VIEW2D \ VOID WEIER WP \ EQTBL GSTBL HASHTBL \ INTABL INTFTBL STBL STRTBL\ TABLE FST SYMS SYMTAB \ IOBCON axiom_algebra_layer_14_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_14)) axiom_algebra_layer_14_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_14))) @ \subsection{Layer15} <>= axiom_algebra_layer_15 = \ DSMP EXPUPXS ARITY \ FRAMALG FRAMALG- MDAGG ODPOL \ PLOT RMCAT2 ROIRC SDPOL \ SMATCAT SMATCAT- TUBETOOL UPXSCCA \ UPXSCCA- JAVACODE POLY BYTEBUF OVERSET axiom_algebra_layer_15_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_15)) axiom_algebra_layer_15_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_15))) @ \subsection{Layer16} <>= axiom_algebra_layer_16 = \ DPMM EFUPXS FFINTBAS FRIDEAL OPERCAT OPERCAT- \ FRIDEAL2 FRMOD \ IBATOOL INTFACT \ MSETAGG MONOGEN MONOGEN- NFINTBAS \ SPACE3 FFF axiom_algebra_layer_16_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_16)) axiom_algebra_layer_16_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_16))) @ \subsection{Layer17} <>= axiom_algebra_layer_17 = \ CCLASS FSAGG2 GALFACT IALGFACT CTORCAT CTORCAT- \ IBACHIN MMLFORM NORMMA ODERED OMSAGG OPSIG \ PERM PERMGRP PRIMES PWFFINTB \ RDIST SAE SAEFACT SAERFFC \ SGCF VIEW3D axiom_algebra_layer_17_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_17)) axiom_algebra_layer_17_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_17))) @ \subsection{Layer18} <>= axiom_algebra_layer_18 = \ INTPACK IPF CATCTOR DOMCTOR CTORCALL \ KAFILE PATRES TBCMPPK axiom_algebra_layer_18_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_18)) axiom_algebra_layer_18_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_18))) @ \subsection{Layer19} <>= axiom_algebra_layer_19 = \ ACPLOT ANTISYM ANY ATTRBUT \ BOP BOP1 COMMONOP COMPCAT \ COMPCAT- DRAW DRAWCFUN DROPT \ DROPT0 D01ANFA D01ASFA D03AGNT \ EP E04AGNT FCPAK1 FEXPR \ FFCAT FFCAT- FFCGP FFNBP \ FFP FLOAT FPARFRAC FR \ FRNAALG FRNAALG- \ FUNCTION GDMP HACKPI \ IDEAL INFORM INFORM1 IPRNTPK \ IR ISUPS KERNEL LIB \ LMDICT LODOOPS MATRIX MKFLCFN \ MSET M3D NAGC02 NAGC05 \ NAGC06 NAGD03 NAGE01 NAGE02 \ NAGE04 NAGF07 NAGS NAGSP \ NREP NUMFMT OC OC- \ ODEPACK ODERAT OMERR OMERRK \ OPTPACK OSI PATTERN OVAR \ PMKERNEL PMSYM PRIMELT \ QALGSET2 QEQUAT RECLOS REP1 \ RESULT QUATCAT QUATCAT- RFFACT \ RMATRIX ROMAN ROUTINE RPOLCAT \ RPOLCAT- RULECOLD SAOS SEGBIND \ SET SPECOUT SQMATRIX SWITCH \ SYSSOLP UTSCAT \ UTSCAT- VARIABLE WFFINTBS SPADPRSR \ PARSER PROPFRML axiom_algebra_layer_19_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_19)) axiom_algebra_layer_19_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_19))) @ \subsection{Layer20} <>= axiom_algebra_layer_20 = \ AF ALGFACT ALGFF ALGMANIP ALGMFACT ALGPKG \ ALGSC AN APPRULE CINTSLPE COMPFACT COMPLEX \ COMPLPAT CMPLXRT CPMATCH CRFP \ CTRIGMNP D01WGTS D02AGNT D03EEFA \ DBLRESP DERHAM DFSFUN DRAWCURV \ E04NAFA E04UCFA EF EFSTRUC \ ELFUTS ESTOOLS EXPEXPAN EXPRODE \ EXPRTUBE EXPR2 FC FDIVCAT \ FDIVCAT- FDIV2 FFCAT2 FLOATCP \ FORDER FORTRAN FSRED FSUPFACT \ FRNAAF2 FSPECF FS2 FS2UPS \ GAUSSFAC GCNAALG GENUFACT GENUPS \ GTSET GPOLSET IAN INEP \ INFPROD0 INFSP INPRODFF INPRODPF \ INTAF INTALG INTEF INTG0 \ INTHERAL INTPAF INTPM INTTOOLS \ ITRIGMNP JORDAN KOVACIC LF \ LIE LODOF LSQM OMEXPR \ MCMPLX MULTFACT NAGD01 NAGD02 \ NAGF01 NAGF02 NAGF04 NCEP \ NLINSOL NSMP NUMERIC OCT \ OCTCT2 ODEPAL ODERTRIC PADE \ PAN2EXPR PDEPACK PFO PFOQ \ PICOERCE PMASSFS PMFS PMPREDFS \ PSETPK QUAT QUATCT2 RADFF \ RDEEF RDEEFS RDIV RSETCAT \ RSETCAT- RULE RULESET SIMPAN \ SFORT SOLVESER SUMFS SUTS \ TOOLSIGN TRIGMNIP TRMANIP ULSCCAT \ ULSCCAT- UPXSSING UTSODE UTSODETL \ UTS2 WUTSET axiom_algebra_layer_20_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_20)) axiom_algebra_layer_20_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_20))) @ \subsection{Layer21} <>= axiom_algebra_layer_21 = \ DEFINTEF DFINTTLS DEFINTRF D01TRNS \ EFULS ESCONT EXPR EXPR2UPS \ FDIV FSCINT FSINT FS2EXPXP \ GSERIES HELLFDIV INVLAPLA IR2F \ IRRF2F LAPLACE LIMITPS LODEEF \ NODE1 ODECONST ODEINT REP \ SOLVERAD SULS SUPXS ULS \ ULSCONS UPXS UPXSCONS UTS axiom_algebra_layer_21_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_21)) axiom_algebra_layer_21_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_21))) @ \subsection{Layer22} <>= axiom_algebra_layer_22 = \ COMBF D01AGNT FSPRMELT \ INBFF LODO LODO1 LODO2 \ NTSCAT REGSET RGCHAIN RSETGCD \ RSDCMPK SFRTCAT SIGNEF SNTSCAT \ SOLVETRA SRDCMPK SREGSET STTF \ SUBSPACE ZDSOLVE axiom_algebra_layer_22_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_22)) axiom_algebra_layer_22_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_22))) @ \subsection{Final layer spad files} <>= axiom_algebra_layer_23 = \ CPIMA IRURPK LAZM3PK LEXTRIPK \ NORMPK QCMPACK RURPK SFRGCD \ SFQCMPK INTRVL ODEEF DOMAIN CATEGORY axiom_algebra_layer_23_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_23)) axiom_algebra_layer_23_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_23))) @ \subsection{User Layer for newly added algebra} Rather than classify newly created algebra into the existing type lattice we add it here. <>= axiom_algebra_layer_user = \ RINTERP ASTCAT ASTCAT- SASTCAT SASTCAT- HEADAST \ LITERAL TYPEAST IMPTAST MAPPAST ATTRAST \ JOINAST IFAST RPTAST WHILEAST INAST CLLCAST \ LSTAST EXITAST RETAST SEGAST PRTDAST CRCAST \ LETAST SUCHAST RDUCEAST COLONAST ADDAST CAPSLAST \ CASEAST HASAST ISAST CATAST WHEREAST COMMAAST \ QQUTAST DEFAST MACROAST SPADXPT SPADAST \ INBFILE OUTBFILE IOBFILE RGBCMDL RGBCSPC \ CTOR IP4ADDR NETCLT INETCLTS \ FMC FMFUN FORTFN FVC FVFUN ASP34 \ ASP1 ASP10 ASP24 ASP4 ASP50 ASP6 \ ASP73 ASP27 ASP28 ASP33 ASP49 ASP7 \ ASP78 ASP9 ASP12 ASP55 ASP8 ASP19 \ ASP20 ASP30 ASP31 ASP35 ASP41 ASP42 \ ASP74 ASP77 ASP80 ASP29 axiom_algebra_layer_user_nrlibs = \ $(addsuffix .NRLIB/code.$(FASLEXT),$(axiom_algebra_layer_user)) axiom_algebra_layer_user_objects = \ $(addprefix $(OUT)/, \ $(addsuffix .$(FASLEXT),$(axiom_algebra_layer_user))) $(OUT)/SASTCAT.$(FASLEXT): $(OUT)/ASTCAT.$(FASLEXT) $(OUT)/LITERAL.$(FASLEXT): $(OUT)/SASTCAT.$(FASLEXT) $(OUT)/HEADAST.$(FASLEXT): $(OUT)/IDENT.$(FASLEXT) $(OUT)/SPADXPT.$(FASLEXT): $(OUT)/ASTCAT.$(FASLEXT) $(OUT)/ATTRAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/TYPEAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/IMPTAST.$(FASLEXT): $(OUT)/TYPEAST.$(FASLEXT) $(OUT)/MAPPAST.$(FASLEXT): $(OUT)/TYPEAST.$(FASLEXT) $(OUT)/SIGAST.$(FASLEXT): $(OUT)/SIG.$(FASLEXT) $(OUT)/IDENT.$(FASLEXT) $(OUT)/JOINAST.$(FASLEXT): $(OUT)/TYPEAST.$(FASLEXT) $(OUT)/IFAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/RPTAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/WHILEAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/INAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/CLLCTAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/LSTAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/EXITAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/RETAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/SEGAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/SEQAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/PRTDAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/CRCEAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/RSTRCAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/LETAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/RDUCEAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/SUCHTAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/COLONAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/ADDAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/CAPSLAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/CASEAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/HASAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/ISAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/CATAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/WHEREAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/COMMAAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/QQUTAST.$(FASLEXT): $(OUT)/SASTCAT.$(FASLEXT) $(OUT)/DEFAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/MACROAST.$(FASLEXT): $(OUT)/SPADXPT.$(FASLEXT) $(OUT)/SPADAST.$(FASLEXT): \ $(addprefix $(OUT)/,$(addsuffix .$(FASLEXT), \ IMPTAST DEFAST MACROAST WHEREAST CATAST CAPSLAST \ SIGAST ATTRAST MAPPAST IFAST RPTAST WHILEAST INAST \ CLLCTAST LSTAST EXITAST RETAST CRCEAST PRTDAST RSTRCAST \ SEGAST SEQAST LETAST SUCHTAST COLONAST CASEAST HASAST \ ISAST)) $(OUT)/INBFILE.$(FASLEXT): $(OUT)/FNAME.$(FASLEXT) \ $(OUT)/INBCON.$(FASLEXT) $(OUT)/STRING.$(FASLEXT) $(OUT)/OUTBFILE.$(FASLEXT): $(OUT)/FNAME.$(FASLEXT) \ $(OUT)/OUTBCON.$(FASLEXT) $(OUT)/STRING.$(FASLEXT) $(OUT)/IOBFILE.$(FASLEXT): $(OUT)/INBFILE.$(FASLEXT) \ $(OUT)/OUTBFILE.$(FASLEXT) $(OUT)/CTOR.$(FASLEXT): $(OUT)/CTORKIND.$(FASLEXT) \ $(OUT)/IDENT.$(FASLEXT) $(OUT)/NETCLT.$(FASLEXT): $(OUT)/IOBCON.$(FASLEXT) $(OUT)/INETCLTS.$(FASLEXT): $(OUT)/NETCLT.$(FASLEXT) $(OUT)/ASP34.$(FASLEXT): $(OUT)/FMC.$(FASLEXT) @ \section{Broken Files} These files are Aldor files \begin{verbatim} axtimer.as Timer iviews.as InventorRenderPackage IVREND ffrac.as FormalFraction FORMAL iviews.as InventorViewPort IVVIEW iviews.as InventorDataSink IVDATA herm.as PackedHermitianSequence PACKED nsfip.as NagSpecialFunctionsInterfacePackage NAGSPE nrc.as NagResultChecks NAGRES nqip.as NagQuadratureInterfacePackage NAGQUA noptip.as NagOptimizationInterfacePackage NAGOPT nepip.as NagEigenInterfacePackage NAGEIG ndftip.as NagDiscreteFourierTransformInterfacePackage NAGDIS \end{verbatim} These domains are referenced but don't exist \begin{verbatim} OBJECT \end{verbatim} \section{The Environment} \subsection{The working directories} We define 5 directories for this build. The{\bf IN} directory contains the pamphlet files for the algebra. These are expanded into the{\bf MID} directory as either .spad or .as files. The .spad files are compiled by the native spad internal compiler. The .as files are compiled using the Aldor compiler. The output of the compilation has two purposes. Part of the information is used to build various database files (daase files). The other part is executable code which is placed in the {\bf OUT} directory. When invoked as ``make document'' we construct the .dvi files in the{\bf DOC} directory. The [[OUTSRC=$(axiom_target_srcdir)/algebra]] subdirectory contains the algebra source files extracted from the pamphlet files. These sources allow the end user to change the algebra if needed. <>= IN=$(srcdir) OUT=$(axiom_targetdir)/algebra DOC=$(axiom_target_docdir)/src/algebra OUTSRC=$(axiom_target_srcdir)/algebra INPUT=../input @ <>= ## We use interpsys, built from previous stage, to bootstrap the algebra ## files. In fact, we use interpsys to build everything. COMPILE_LISP = $(INTERPSYS) --compile --output=$@ $< @ \subsection{The interpsys variable} The {\bf interpsys} image is the compile-time environment for algebra files. <>= INTERPSYS = ../interp/interpsys$(EXEEXT) -- --system="$(AXIOM)" \ --sysalg="$(axiom_src_datadir)/algebra/" @ \subsection{The SPADFILES list} Note that we have excluded {\bf mlift.spad.jhd} from this list. We need to figure out which mlift.spad to keep. <>= SPADFILES= \ ${OUTSRC}/acplot.spad ${OUTSRC}/aggcat2.spad ${OUTSRC}/aggcat.spad \ ${OUTSRC}/algcat.spad ${OUTSRC}/algext.spad ${OUTSRC}/algfact.spad \ ${OUTSRC}/algfunc.spad ${OUTSRC}/allfact.spad ${OUTSRC}/alql.spad \ ${OUTSRC}/annacat.spad ${OUTSRC}/any.spad ${OUTSRC}/array1.spad \ ${OUTSRC}/array2.spad ${OUTSRC}/asp.spad ${OUTSRC}/attreg.spad \ ${OUTSRC}/bags.spad ${OUTSRC}/bezout.spad ${OUTSRC}/boolean.spad \ ${OUTSRC}/brill.spad \ ${OUTSRC}/c02.spad ${OUTSRC}/c05.spad ${OUTSRC}/c06.spad \ ${OUTSRC}/card.spad ${OUTSRC}/carten.spad ${OUTSRC}/catdef.spad \ ${OUTSRC}/cden.spad ${OUTSRC}/clifford.spad ${OUTSRC}/clip.spad \ ${OUTSRC}/cmplxrt.spad ${OUTSRC}/coerce.spad ${OUTSRC}/color.spad \ ${OUTSRC}/combfunc.spad ${OUTSRC}/combinat.spad ${OUTSRC}/complet.spad \ ${OUTSRC}/constant.spad ${OUTSRC}/contfrac.spad ${OUTSRC}/cont.spad \ ${OUTSRC}/coordsys.spad ${OUTSRC}/cra.spad ${OUTSRC}/crfp.spad \ ${OUTSRC}/curve.spad ${OUTSRC}/cycles.spad ${OUTSRC}/cyclotom.spad \ ${OUTSRC}/d01agents.spad ${OUTSRC}/d01Package.spad \ ${OUTSRC}/d01routine.spad ${OUTSRC}/d01.spad ${OUTSRC}/d01transform.spad \ ${OUTSRC}/d01weights.spad ${OUTSRC}/d02agents.spad \ ${OUTSRC}/d02Package.spad ${OUTSRC}/d02routine.spad ${OUTSRC}/d02.spad \ ${OUTSRC}/d03agents.spad ${OUTSRC}/d03Package.spad \ ${OUTSRC}/d03routine.spad ${OUTSRC}/d03.spad ${OUTSRC}/ddfact.spad \ ${OUTSRC}/defaults.spad ${OUTSRC}/defintef.spad ${OUTSRC}/defintrf.spad \ ${OUTSRC}/degred.spad ${OUTSRC}/derham.spad ${OUTSRC}/dhmatrix.spad \ ${OUTSRC}/divisor.spad ${OUTSRC}/dpolcat.spad ${OUTSRC}/drawopt.spad \ ${OUTSRC}/drawpak.spad ${OUTSRC}/draw.spad \ ${OUTSRC}/e01.spad ${OUTSRC}/e02.spad ${OUTSRC}/e04agents.spad \ ${OUTSRC}/e04Package.spad ${OUTSRC}/e04routine.spad ${OUTSRC}/e04.spad \ ${OUTSRC}/efstruc.spad ${OUTSRC}/efuls.spad ${OUTSRC}/efupxs.spad \ ${OUTSRC}/eigen.spad ${OUTSRC}/elemntry.spad ${OUTSRC}/elfuts.spad \ ${OUTSRC}/equation1.spad ${OUTSRC}/equation2.spad ${OUTSRC}/error.spad \ ${OUTSRC}/expexpan.spad ${OUTSRC}/expr2ups.spad \ ${OUTSRC}/exprode.spad ${OUTSRC}/expr.spad \ ${OUTSRC}/f01.spad ${OUTSRC}/f02.spad ${OUTSRC}/f04.spad \ ${OUTSRC}/f07.spad ${OUTSRC}/facutil.spad ${OUTSRC}/ffcat.spad \ ${OUTSRC}/ffcg.spad ${OUTSRC}/fff.spad ${OUTSRC}/ffhom.spad \ ${OUTSRC}/ffnb.spad ${OUTSRC}/ffpoly2.spad ${OUTSRC}/ffpoly.spad \ ${OUTSRC}/ffp.spad ${OUTSRC}/ffx.spad \ ${OUTSRC}/files.spad ${OUTSRC}/float.spad ${OUTSRC}/fmod.spad \ ${OUTSRC}/fname.spad ${OUTSRC}/fnla.spad ${OUTSRC}/formula.spad \ ${OUTSRC}/fortcat.spad ${OUTSRC}/fortmac.spad ${OUTSRC}/fortpak.spad \ ${OUTSRC}/fortran.spad ${OUTSRC}/forttyp.spad ${OUTSRC}/fourier.spad \ ${OUTSRC}/fparfrac.spad ${OUTSRC}/fraction.spad ${OUTSRC}/free.spad \ ${OUTSRC}/fr.spad ${OUTSRC}/fs2expxp.spad ${OUTSRC}/fs2ups.spad \ ${OUTSRC}/fspace.spad ${OUTSRC}/funcpkgs.spad ${OUTSRC}/functions.spad \ ${OUTSRC}/galfact.spad ${OUTSRC}/galfactu.spad ${OUTSRC}/galpolyu.spad \ ${OUTSRC}/galutil.spad ${OUTSRC}/gaussfac.spad ${OUTSRC}/gaussian.spad \ ${OUTSRC}/gbeuclid.spad ${OUTSRC}/gbintern.spad ${OUTSRC}/gb.spad \ ${OUTSRC}/gdirprod.spad ${OUTSRC}/gdpoly.spad ${OUTSRC}/geneez.spad \ ${OUTSRC}/generic.spad ${OUTSRC}/genufact.spad ${OUTSRC}/genups.spad \ ${OUTSRC}/ghensel.spad ${OUTSRC}/gpgcd.spad ${OUTSRC}/gpol.spad \ ${OUTSRC}/grdef.spad ${OUTSRC}/groebf.spad ${OUTSRC}/groebsol.spad \ ${OUTSRC}/gseries.spad \ ${OUTSRC}/ideal.spad ${OUTSRC}/idecomp.spad ${OUTSRC}/indexedp.spad \ ${OUTSRC}/infprod.spad ${OUTSRC}/intaf.spad ${OUTSRC}/intalg.spad \ ${OUTSRC}/intaux.spad ${OUTSRC}/intclos.spad ${OUTSRC}/intef.spad \ ${OUTSRC}/integer.spad ${OUTSRC}/integrat.spad \ ${OUTSRC}/interval.spad \ ${OUTSRC}/intfact.spad ${OUTSRC}/intpm.spad \ ${OUTSRC}/intrf.spad \ ${OUTSRC}/irexpand.spad \ ${OUTSRC}/irsn.spad ${OUTSRC}/ituple.spad \ ${OUTSRC}/kl.spad ${OUTSRC}/kovacic.spad \ ${OUTSRC}/laplace.spad ${OUTSRC}/laurent.spad ${OUTSRC}/leadcdet.spad \ ${OUTSRC}/lie.spad ${OUTSRC}/limitps.spad ${OUTSRC}/lindep.spad \ ${OUTSRC}/lingrob.spad ${OUTSRC}/liouv.spad ${OUTSRC}/listgcd.spad \ ${OUTSRC}/list.spad ${OUTSRC}/lmdict.spad ${OUTSRC}/lodof.spad \ ${OUTSRC}/lodop.spad ${OUTSRC}/lodo.spad \ ${OUTSRC}/manip.spad ${OUTSRC}/mappkg.spad ${OUTSRC}/matcat.spad \ ${OUTSRC}/matfuns.spad ${OUTSRC}/mathml.spad \ ${OUTSRC}/matrix.spad ${OUTSRC}/matstor.spad \ ${OUTSRC}/mesh.spad ${OUTSRC}/mfinfact.spad ${OUTSRC}/misc.spad \ ${OUTSRC}/mkfunc.spad ${OUTSRC}/mkrecord.spad \ ${OUTSRC}/mlift.spad ${OUTSRC}/moddfact.spad ${OUTSRC}/modgcd.spad \ ${OUTSRC}/modmonom.spad ${OUTSRC}/modmon.spad ${OUTSRC}/modring.spad \ ${OUTSRC}/moebius.spad ${OUTSRC}/mring.spad ${OUTSRC}/mset.spad \ ${OUTSRC}/mts.spad ${OUTSRC}/multfact.spad ${OUTSRC}/multpoly.spad \ ${OUTSRC}/multsqfr.spad \ ${OUTSRC}/naalgc.spad ${OUTSRC}/naalg.spad \ ${OUTSRC}/newdata.spad ${OUTSRC}/newpoint.spad \ ${OUTSRC}/newpoly.spad ${OUTSRC}/nlinsol.spad ${OUTSRC}/nlode.spad \ ${OUTSRC}/npcoef.spad \ ${OUTSRC}/nregset.spad \ ${OUTSRC}/nsregset.spad ${OUTSRC}/numeigen.spad ${OUTSRC}/numeric.spad \ ${OUTSRC}/numode.spad ${OUTSRC}/numquad.spad ${OUTSRC}/numsolve.spad \ ${OUTSRC}/numtheor.spad \ ${OUTSRC}/oct.spad ${OUTSRC}/odealg.spad ${OUTSRC}/odeef.spad \ ${OUTSRC}/oderf.spad ${OUTSRC}/omcat.spad ${OUTSRC}/omdev.spad \ ${OUTSRC}/omerror.spad ${OUTSRC}/omserver.spad ${OUTSRC}/opalg.spad \ ${OUTSRC}/openmath.spad ${OUTSRC}/op.spad ${OUTSRC}/ore.spad \ ${OUTSRC}/outform.spad ${OUTSRC}/out.spad \ ${OUTSRC}/pade.spad ${OUTSRC}/padiclib.spad ${OUTSRC}/padic.spad \ ${OUTSRC}/paramete.spad ${OUTSRC}/partperm.spad ${OUTSRC}/patmatch1.spad \ ${OUTSRC}/patmatch2.spad ${OUTSRC}/pattern.spad ${OUTSRC}/pcurve.spad \ ${OUTSRC}/pdecomp.spad ${OUTSRC}/perman.spad ${OUTSRC}/permgrps.spad \ ${OUTSRC}/perm.spad ${OUTSRC}/pfbr.spad ${OUTSRC}/pfo.spad \ ${OUTSRC}/pfr.spad ${OUTSRC}/pf.spad ${OUTSRC}/pgcd.spad \ ${OUTSRC}/pgrobner.spad ${OUTSRC}/pinterp.spad ${OUTSRC}/pleqn.spad \ ${OUTSRC}/plot3d.spad ${OUTSRC}/plot.spad ${OUTSRC}/plottool.spad \ ${OUTSRC}/polset.spad ${OUTSRC}/poltopol.spad ${OUTSRC}/polycat.spad \ ${OUTSRC}/poly.spad ${OUTSRC}/primelt.spad ${OUTSRC}/print.spad \ ${OUTSRC}/product.spad ${OUTSRC}/prs.spad ${OUTSRC}/prtition.spad \ ${OUTSRC}/pscat.spad ${OUTSRC}/pseudolin.spad ${OUTSRC}/ptranfn.spad \ ${OUTSRC}/puiseux.spad \ ${OUTSRC}/qalgset.spad ${OUTSRC}/quat.spad \ ${OUTSRC}/radeigen.spad ${OUTSRC}/radix.spad ${OUTSRC}/random.spad \ ${OUTSRC}/ratfact.spad ${OUTSRC}/rdeef.spad ${OUTSRC}/rderf.spad \ ${OUTSRC}/rdesys.spad ${OUTSRC}/real0q.spad ${OUTSRC}/realzero.spad \ ${OUTSRC}/reclos.spad ${OUTSRC}/regset.spad ${OUTSRC}/rep1.spad \ ${OUTSRC}/rep2.spad ${OUTSRC}/resring.spad ${OUTSRC}/retract.spad \ ${OUTSRC}/rf.spad ${OUTSRC}/riccati.spad ${OUTSRC}/rinterp.spad \ ${OUTSRC}/routines.spad \ ${OUTSRC}/rule.spad \ ${OUTSRC}/seg.spad ${OUTSRC}/setorder.spad ${OUTSRC}/sets.spad \ ${OUTSRC}/sex.spad ${OUTSRC}/sf.spad ${OUTSRC}/sgcf.spad \ ${OUTSRC}/sign.spad ${OUTSRC}/si.spad ${OUTSRC}/smith.spad \ ${OUTSRC}/solvedio.spad ${OUTSRC}/solvefor.spad ${OUTSRC}/solvelin.spad \ ${OUTSRC}/solverad.spad ${OUTSRC}/sortpak.spad ${OUTSRC}/space.spad \ ${OUTSRC}/special.spad ${OUTSRC}/sregset.spad ${OUTSRC}/s.spad \ ${OUTSRC}/stream.spad ${OUTSRC}/string.spad ${OUTSRC}/sttaylor.spad \ ${OUTSRC}/sttf.spad ${OUTSRC}/sturm.spad ${OUTSRC}/suchthat.spad \ ${OUTSRC}/suls.spad ${OUTSRC}/sum.spad ${OUTSRC}/sups.spad \ ${OUTSRC}/supxs.spad ${OUTSRC}/suts.spad ${OUTSRC}/symbol.spad \ ${OUTSRC}/syssolp.spad ${OUTSRC}/system.spad \ ${OUTSRC}/tableau.spad ${OUTSRC}/table.spad ${OUTSRC}/taylor.spad \ ${OUTSRC}/tex.spad ${OUTSRC}/tools.spad ${OUTSRC}/transsolve.spad \ ${OUTSRC}/tree.spad ${OUTSRC}/trigcat.spad ${OUTSRC}/triset.spad \ ${OUTSRC}/tube.spad ${OUTSRC}/twofact.spad \ ${OUTSRC}/unifact.spad ${OUTSRC}/updecomp.spad ${OUTSRC}/updivp.spad \ ${OUTSRC}/utsode.spad \ ${OUTSRC}/variable.spad ${OUTSRC}/vector.spad ${OUTSRC}/view2D.spad \ ${OUTSRC}/view3D.spad ${OUTSRC}/viewDef.spad ${OUTSRC}/viewpack.spad \ ${OUTSRC}/void.spad \ ${OUTSRC}/weier.spad ${OUTSRC}/wtpol.spad \ ${OUTSRC}/xlpoly.spad ${OUTSRC}/xpoly.spad \ ${OUTSRC}/ystream.spad \ ${OUTSRC}/zerodim.spad @ \subsection{The ALDORFILES list} <>= ALDORFILES= \ axtimer.as \ ffrac.as \ herm.as \ interval.as \ invnode.as \ invrender.as \ invtypes.as \ invutils.as \ iviews.as \ ndftip.as \ nepip.as \ noptip.as nqip.as \ nrc.as nsfip.as @ \section{Test Cases} <>= TESTS=${INPUT}/INTHEORY.input ${INPUT}/VIEW2D.input ${INPUT}/TESTFR.input @ <>= ${INPUT}/TESTFR.input: $(srcdir)/fr.spad.pamphlet $(axiom_build_document) --tangle='TEST FR' --output=$@ $< ${INPUT}/INTHEORY.input: $(srcdir)/numtheor.spad.pamphlet $(axiom_build_document) --tangle='TEST INTHEORY' --output=$@ $< ${INPUT}/VIEW2D.input: $(srcdir)/view2D.spad.pamphlet $(axiom_build_document) --tangle='TEST VIEW2D' --output=$@ $< @ \section{The Makefile Stanzas} A [[spad]] pamphlet can contain many Axiom [[categories]], [[domains]], and [[packages]]. For the purpose of explanation we assume that the pamphlet file is named [[foo.spad.pamphlet]]. It contains the domains [[BAR]], [[BAX]], and [[BAZ]]. Thus there will be a subsection named [[foo.spad]]. Since pamphlet files (e.g. [[foo.spad.pamphlet]] contain a spad file e.g. [[foo.spad]], it follows that every subsection contains a Makefile stanza that extract the [[foo.spad]] file using [[notangle]]. Since pamphlet files are intended as documents it follows that each subsection contains a Makefile stanza that extracts a [[dvi]] file using [[noweave]]. We could have a category, domain, or package that is in the ``bootstrap'' list. Bootstrap spad files contain their generated lisp code in special sections. The way bootstrapping works is that we extract the lisp code and compile it rather than extracting the spad code. We do this because we need the domain to exist before we can compile the domain. Some domains depend on themselves directly. Some domains depend on themselves thru a long chain of other domains. In either case we can't compile the domain until it exists so we cache the generated lisp code and, when we need to bootstrap the domain, we compile the raw lisp rather than the spad. This will only happen when the system is built from scratch. Once the system has been built the bootstrap code is no longer executed and these algebra files will appear as normal algebra files. That means that once the system has been built once only the last three rules will ever be executed. The first two rules happen when the system is built from scratch. A 5 stanza group for this case performs the following functions: \begin{enumerate} \item compile and copy the bootstrap lisp to the final algebra directory \item compile the extracted [[BAR]] domain \item copy the compiled [[BAR]] to the final algebra directory \end{enumerate} The subtle point here occurs in the first item. The bootstrap code group (in the [[layer0 bootstrap]] code chunk above) asks for the compiled [[.$(FASLEXT)]] files in the \File{strap/} directory. Essentially this code group calls for intermediate compiled files. This triggers the bootstrap stanzas (items 1 and 2 above). All of the other layer chunks ask for compiled code in the [[\${OUT}]] directory which is the final algebra directory. The bootstrap process works because first we ask for the compiled lisp code stanzas (the \File{strap/BAR.$(FASLEXT)} files), THEN we ask for the final algebra code stanzas (the [[\${OUT}/BAR.$(FASLEXT)]] files). This is a very subtle point so think it through carefully. The layer0 bootstrap list is the only file list that calls for \File{strap/} files. All other layers ask for [[\${OUT}]] files. Make sure you understand this before you change things. If you break it the world will no longer compile. So we have a 3 stanza group for normal files, a 3+2 (5) stanza group for normal files with default code, and a 3+2 (5) stanza group for normal files that need to be bootstrapped. There is another combination that occurs, namely bootstrap code that also contains default code which gives a 3+2+2+2 (9) stanza case. (see TSETCAT for an example. Be sure to read the items in reverse order). A 9 stanza group for this case performs the following functions: \begin{enumerate} \item extract the bootstrap \File{BAR.lsp} from the \File{foo.spad.pamphlet} \item compile the bootstrap \File{BAR.lsp} to the \File{strap/} directory \item extract the bootstrap \File{BAR-.lsp} from the \File{foo.spad.pamphlet} \item compile the bootstrap \File{BAR-.lsp} to the \File{strap/} directory \item extract the spad \File{BAR.spad} from the pamphlet \File{foo.spad.pamphlet} \item compile the extracted \File{BAR.spad} domain (to get [[BAR.$(FASLEXT)]]) \item copy the \File{BAR.$(FASLEXT)} to the final algebra directory \item compile the extracted \File{BAR-.spad} domain (to get [[BAR-.$(FASLEXT)]]) \item copy the [[BAR-.$(FASLEXT)]] to the final algebra directory \end{enumerate} As you can see this is just the combination of the two possible 5 stanza case. We just have to deal with the [[BAR-]] both in regular and bootstrap files. The first four stanzas will only happen when the system is built from scratch. Once the system is built these four rules no longer apply and these stanzas effectively act like the 5 stanza rules above. I'm sure all of this seems confusing but it is very stylized code. Basically you need to figure out which kind of stanza group you need, copy an existing stanza group, and do a correct renaming of the parts. The decision tree looks something like: \begin{verbatim} IF (you have a regular spad domain) THEN use a 3 stanza form (see YSTREAM) IF (you have a default spad domain (it generates [[-]] files)) AND (it does not require bootstrapping) THEN use the first 5 stanza form explained above (see LIECAT) IF (you have a normal spad domain) AND (it requires bootstrapping) THEN use the second 5 stanza form explained above (see VECTOR) IF (you have a default spad domain (it generates [[-]] files)) AND (it requires bootstrapping) THEN use the 9 stanza form explained above (see TSETCAT) \end{verbatim} \section{Generic Make Rules} The idea is to use generic rules to try to cut down the size of this file. This Makefile works very hard to cache intermediate results in order to minimize the re-build time. The cached files are kept in the current build and \File{strap/} directories. If one of these files disappears but the original pamphlet file is unchanged we only need to rebuild the intermediate file. These rule will attempt to do that and they succeed however these are intermediate files created by implicit rules so they would normally be deleted. To prevent the removal the NRLIB directory and its contents, the files are marked as .PRECIOUS. The output of the compile step is saved in a file of the same name and extension .$(FASLEXT)ut in the \${MID} directory. These files are useful for deriving the dependencies by scanning the ``Loading ...'' messages. <>= .PRECIOUS: $(OUT)/%.$(FASLEXT) ${OUT}/%.$(FASLEXT): %.NRLIB/code.$(FASLEXT) cp $< $@ @ <>= .PREVIOUS: %.spad .PRECIOUS: %.NRLIB/code.$(FASLEXT) %.NRLIB/code.$(FASLEXT): %.spad ${INTERPSYS} --strap=strap --system-algebra --optimize=2 --compile $< @ <>= # Compile bootstrap file to machine object code, and the result # immediately available for AXIOMsys consumption. strap/%.$(FASLEXT): $(srcdir)/strap/%.lsp $(COMPILE_LISP) @ <>= $(OUTSRC)/%.spad: mk-target-src-algabra-dir ${OUTSRC}/%.spad: $(srcdir)/%.spad.pamphlet $(axiom_build_document) --tangle --output=$@ $< .PHONY: mk-target-src-algabra-dir mk-target-src-algabra-dir: @ [ -d $(OUTSRC) ] || $(mkdir_p) $(OUTSRC) @ <>= .PRECIOUS: $(builddir)/%.tex .PRECIOUS: $(builddir)/%.dvi $(DOC)/%.dvi: mk-target-doc-dir .PHONY: mk-target-doc-dir mk-target-doc-dir: @ [ -d $(DOC) ] || $(mkdir_p) $(DOC) $(DOC)/%.dvi: $(builddir)/%.dvi @cp -p $< $@ $(builddir)/%.dvi: $(axiom_build_texdir)/diagrams.tex \ $(axiom_build_texdir)/axiom.sty $(builddir)/%.dvi: $(builddir)/%.tex $(axiom_build_document) --latex $< $(builddir)/%.tex: $(srcdir)/%.pamphlet $(axiom_build_document) --weave --output=$@ $< $(axiom_build_texdir)/diagrams.tex: $(axiom_src_docdir)/diagrams.tex @cp -p $< $@ @ <>= <> <> <> <> <> SPADPRSR.NRLIB/code.$(FASLEXT): spad-parser.spad ${INTERPSYS} --system-algebra --compile $< PARSER.NRLIB/code.$(FASLEXT): script-parser.spad ${INTERPSYS} --system-algebra --compile $< @ <>= ${DOC}/diagrams.tex: $(axiom_src_docdir)/diagrams.tex @cp -p $< $@ @ \section{Pamphlet file structure} Because the individual .spad files are grouped into higher-level algebra pamphlet files, the rules for extracting them are coded below as simple ``awk'' scripts that are called when the Makefile is constructed. There are, at present, 3 kinds of algebra files to be handled. First we have [[.as]] files which use the [[aldor]] compiler. These are ignored here as the compiler is not yet integrated. Second, there are the bootstrap files. These files live within their respective pamphlet files and are "captured" lisp code. These are necessary to create the algebra. See the [[src/algebra/Makefile.pamphlet]] for details. Third, there are 3 "types" of algebra which are all treated the same at compile time, namely the "domain", "category", and "package" algebra. \subsection{Finding the algebra code} NOTE: This construct is now moved to configure time. Update. Step 1 is to scan all of the algebra pamphlet files for the chunk names which contain the string "domain", "package", or "category". This is done using egrep (same as grep -E, which means that the pattern is an extended regular expression) because extended regular expressions allows the use of alternatives written as (domain|package|category). Thus the command \begin{verbatim} egrep '@<<(domain|package|category) .*>>=' *.spad.pamphlet \end{verbatim} will scan the algebra files looking for special chunknames. Axiom's chunk names are written in a stylized form so that each algebra chunk name begins with one of those three symbols. Thus in zerodim.spad.pamphlet the LexTriangularPackage chunkname is: \begin{verbatim} @<> \end{verbatim} so this egrep will generate an output line, prefixed by the filename that looks like: \begin{verbatim} zerodim.spad.pamphlet:@<>= \end{verbatim} There can be many lines of output per pamphlet file, one for each domain, package and category cod chunk contained in the file. Step 2 is an [[awk]] command line. \subsection{Write the Makefile stanzas for the algebra files} NOTE: This construct is now moved to configure time. [awk] processes each line of the [[egrep]] output. The awk script uses [[-F:]] which is a flag that says that a [[:]] is the field separator. As a result the \$1 and \$2 in the awk script refer to the parts of the egrep output that come before and after the [[:]] respectively. The variable [[chunk]] is assigned the actual chunk name minus the @<< and >>= delimiters. In the example given above this will become \begin{verbatim} package LEXTRIPK LexTriangularPackage \end{verbatim} The call to [[split]] splits the chunk into parts separated by spaces. Thus \begin{verbatim} part[1]=package part[2]=LEXTRIPK part[3]=LexTriangularPackage \end{verbatim} The variable [[spadfile]] in the above example is set to \begin{verbatim} ${MID}/LEXTRIPK.spad \end{verbatim} Finally, in the domain example given above we print two lines. The first line is the Makefile stanza header which depends on the original [[zerodim.spad.pamphlet]] file. The second line is the body of the makefile stanza which calls notangle to extract the algebra from the original pamphlet using the chunk name and writes it to the intermediate subdirectory. In the case above this would resolve to [[\${MID}/LEXTRIPK.spad]]. For the line given above it outputs the following: \begin{verbatim} ${MID}/LEXTRIPK.spad: $(srcdir)/zerodim.spad.pamphlet $(axiom_build_document) --tangle='package LEXTRIPK LexTriangularPackage' --output=$@ $< \end{verbatim} \section{Stage markers} We output these as each stage completes. <>= $(axiom_algebra_layer_0_objects): strap-stamp $(axiom_algebra_layer_1_objects): 0-stamp $(axiom_algebra_layer_2_objects): 1-stamp $(axiom_algebra_layer_3_objects): 2-stamp $(axiom_algebra_layer_4_objects): 3-stamp $(axiom_algebra_layer_5_objects): 4-stamp $(axiom_algebra_layer_6_objects): 5-stamp $(axiom_algebra_layer_7_objects): 6-stamp $(axiom_algebra_layer_8_objects): 7-stamp $(axiom_algebra_layer_9_objects): 8-stamp $(axiom_algebra_layer_10_objects): 9-stamp $(axiom_algebra_layer_11_objects): 10-stamp $(axiom_algebra_layer_12_objects): 11-stamp $(axiom_algebra_layer_13_objects): 12-stamp $(axiom_algebra_layer_14_objects): 13-stamp $(axiom_algebra_layer_15_objects): 14-stamp $(axiom_algebra_layer_16_objects): 15-stamp $(axiom_algebra_layer_17_objects): 16-stamp $(axiom_algebra_layer_18_objects): 17-stamp $(axiom_algebra_layer_19_objects): 18-stamp $(axiom_algebra_layer_20_objects): 19-stamp $(axiom_algebra_layer_21_objects): 20-stamp $(axiom_algebra_layer_22_objects): 21-stamp $(axiom_algebra_layer_23_objects): 22-stamp $(axiom_algebra_bootstrap_objects): 23-stamp $(axiom_algebra_layer_user_objects): bootstrap-stamp strap-stamp: $(axiom_algebra_layer_strap_objects) @ rm -f strap-stamp @ $(STAMP) strap-stamp @ echo ===================================== @ echo === algebra bootstrap complete ====== @ echo ===================================== 0-stamp: strap-stamp $(axiom_algebra_layer_0_objects) @ rm -f 0-stamp @ $(STAMP) 0-stamp @ echo ================================== @ echo === layer 0 of 23 complete ====== @ echo ================================== 1-stamp: 0-stamp $(axiom_algebra_layer_1_objects) @ rm -f 1-stamp @ $(STAMP) 1-stamp @ echo ================================== @ echo === layer 1 of 23 complete ====== @ echo ================================== 2-stamp: 1-stamp $(axiom_algebra_layer_2_objects) @ rm -f 2-stamp @ $(STAMP) 2-stamp @ echo ================================== @ echo === layer 2 of 23 complete ====== @ echo ================================== 3-stamp: 2-stamp $(axiom_algebra_layer_3_objects) @ rm -f 3-stamp @ $(STAMP) 3-stamp @ echo ================================== @ echo === layer 3 of 23 complete ====== @ echo ================================== 4-stamp: 3-stamp $(axiom_algebra_layer_4_objects) @ rm -f 4-stamp @ $(STAMP) 4-stamp @ echo ================================== @ echo === layer 4 of 23 complete ====== @ echo ================================== 5-stamp: 4-stamp $(axiom_algebra_layer_5_objects) @ rm -f 5-stamp @ $(STAMP) 5-stamp @ echo ================================== @ echo === layer 5 of 23 complete ====== @ echo ================================== 6-stamp: 5-stamp $(axiom_algebra_layer_6_objects) @ rm -f 6-stamp @ $(STAMP) 6-stamp @ echo ================================== @ echo === layer 6 of 23 complete ====== @ echo ================================== 7-stamp: 6-stamp $(axiom_algebra_layer_7_objects) @ rm -f 7-stamp @ $(STAMP) 7-stamp @ echo ================================== @ echo === layer 7 of 23 complete ====== @ echo ================================== 8-stamp: 7-stamp $(axiom_algebra_layer_8_objects) @ rm -f 8-stamp @ $(STAMP) 8-stamp @ echo ================================== @ echo === layer 8 of 23 complete ====== @ echo ================================== 9-stamp: 8-stamp $(axiom_algebra_layer_9_objects) @ rm -f 9-stamp @ $(STAMP) 9-stamp @ echo ================================== @ echo === layer 9 of 23 complete ====== @ echo ================================== 10-stamp: 9-stamp $(axiom_algebra_layer_10_objects) @ rm -f 10-stamp @ $(STAMP) 10-stamp @ echo ================================== @ echo === layer 10 of 23 complete ====== @ echo ================================== 11-stamp: 10-stamp $(axiom_algebra_layer_11_objects) @ rm -f 11-stamp @ $(STAMP) 11-stamp @ echo ================================== @ echo === layer 11 of 23 complete ====== @ echo ================================== 12-stamp: 11-stamp $(axiom_algebra_layer_12_objects) @ rm -f 12-stamp @ $(STAMP) 12-stamp @ echo ================================== @ echo === layer 12 of 23 complete ====== @ echo ================================== 13-stamp: 12-stamp $(axiom_algebra_layer_13_objects) @ rm -f 13-stamp @ $(STAMP) 13-stamp @ echo ================================== @ echo === layer 13 of 23 complete ====== @ echo ================================== 14-stamp: 13-stamp $(axiom_algebra_layer_14_objects) @ rm -f 14-stamp @ $(STAMP) 14-stamp @ echo ================================== @ echo === layer 14 of 23 complete ====== @ echo ================================== 15-stamp: 14-stamp $(axiom_algebra_layer_15_objects) @ rm -f 15-stamp @ $(STAMP) 15-stamp @ echo ================================== @ echo === layer 15 of 23 complete ====== @ echo ================================== 16-stamp: 15-stamp $(axiom_algebra_layer_16_objects) @ rm -f 16-stamp @ $(STAMP) 16-stamp @ echo ================================== @ echo === layer 16 of 23 complete ====== @ echo ================================== 17-stamp: 16-stamp $(axiom_algebra_layer_17_objects) @ rm -f 17-stamp @ $(STAMP) 17-stamp @ echo ================================== @ echo === layer 17 of 23 complete ====== @ echo ================================== 18-stamp: 17-stamp $(axiom_algebra_layer_18_objects) @ rm -f 18-stamp @ $(STAMP) 18-stamp @ echo ================================== @ echo === layer 18 of 23 complete ====== @ echo ================================== 19-stamp: 18-stamp $(axiom_algebra_layer_19_objects) @ rm -f 19-stamp @ $(STAMP) 19-stamp @ echo ================================== @ echo === layer 19 of 23 complete ====== @ echo ================================== 20-stamp: 19-stamp $(axiom_algebra_layer_20_objects) @ rm -f 20-stamp @ $(STAMP) 20-stamp @ echo ================================== @ echo === layer 20 of 23 complete ====== @ echo ================================== 21-stamp: 20-stamp $(axiom_algebra_layer_21_objects) @ rm -f 21-stamp @ $(STAMP) 21-stamp @ echo ================================== @ echo === layer 21 of 23 complete ====== @ echo ================================== 22-stamp: 21-stamp $(axiom_algebra_layer_22_objects) @ rm -f 22-stamp @ $(STAMP) 22-stamp @ echo ================================== @ echo === layer 22 of 23 complete ====== @ echo ================================== 23-stamp: 22-stamp $(axiom_algebra_layer_23_objects) @ rm -f 23-stamp @ $(STAMP) 23-stamp @ echo ================================== @ echo === layer 23 of 23 complete ====== @ echo ================================== bootstrap-stamp: 23-stamp $(axiom_algebra_bootstrap_objects) @ rm -f bootstrap-stamp @ $(STAMP) bootstrap-stamp @ echo ================================== @ echo === algebra complete ====== @ echo ================================== user-stamp: $(axiom_algebra_layer_user_objects) @ rm -f user-stamp @ $(STAMP) user-stamp @ \section{The Makefile} <<*>>= <> subdir = src/algebra/ <> <> <> <> <> <> <> <> <> <> <> <> <> <> <> <> <> <> <> <> <> <> <> <> <> <> <> .PHONY: all all-algebra mkdir-output-directory all: all-ax all-ax all-algebra: stamp @ echo finished $(builddir) stamp: mkdir-output-directory ${SPADFILES} user-stamp ${TESTS} -rm -f stamp $(STAMP) stamp mkdir-output-directory: $(mkdir_p) $(OUTSRC) everything: check lib db cmd gloss @ echo 4303 invoking make in `pwd` with parms: check: @ echo 4305 Checking that INTERP.EXPOSED and NRLIBs are consistent @ echo 4306 libcheck needs to use exposed.lsp, not INTERP.EXPOSED <> <> <> <> .PHONY: all-algstrap all-algstrap: $(addsuffix .NRLIB/code.lsp,$(axiom_algebra_bootstrap)) for a in $(axiom_algebra_bootstrap); do \ old=$(srcdir)/strap/$$a.lsp; new=$$a.NRLIB/code.lsp; \ cmp -s $$new $$old || cp -p $$new $$old || exit 1; \ done mostlyclean-local: @rm -f $(OUT)/*.$(FASLEXT) $(OUT)/*.daase @rm -rf *.NRLIB @rm -rf *.DAASE *.daase libdb.text @rm -rf strap @rm -f *stamp clean-local: mostlyclean-local distclean-local: clean-local include extract-spad.mk .NOTPARALLEL: @ \eject \begin{thebibliography}{99} \bibitem{1} nothing \end{thebibliography} \end{document}