-- Copyright (c) 1991-2002, The Numerical Algorithms Group Ltd. -- All rights reserved. -- Copyright (C) 2007-2010, Gabriel Dos Reis. -- All rights reserved. -- -- Redistribution and use in source and binary forms, with or without -- modification, are permitted provided that the following conditions are -- met: -- -- - Redistributions of source code must retain the above copyright -- notice, this list of conditions and the following disclaimer. -- -- - Redistributions in binary form must reproduce the above copyright -- notice, this list of conditions and the following disclaimer in -- the documentation and/or other materials provided with the -- distribution. -- -- - Neither the name of The Numerical Algorithms Group Ltd. nor the -- names of its contributors may be used to endorse or promote products -- derived from this software without specific prior written permission. -- -- THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS -- IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED -- TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A -- PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER -- OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, -- EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, -- PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR -- PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF -- LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING -- NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS -- SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. import nruncomp import g_-error import database import modemap namespace BOOT module define where compDefine: (%Form,%Mode,%Env) -> %Maybe %Triple compSubDomain: (%Form,%Mode,%Env) -> %Maybe %Triple compCapsule: (%Form, %Mode, %Env) -> %Maybe %Triple compJoin: (%Form,%Mode,%Env) -> %Maybe %Triple compAdd: (%Form, %Mode, %Env) -> %Maybe %Triple compCategory: (%Form,%Mode,%Env) -> %Maybe %Triple --% $newCompCompare := false ++ List of mutable domains. $mutableDomains := nil ++ True if the current constructor being compiled instantiates ++ mutable domains or packages. Default is `false'. $mutableDomain := false ++ when non nil, holds the declaration number of a function in a capsule. $suffix := nil $doNotCompileJustPrint := false ++ stack of pending capsule function definitions. $capsuleFunctionStack := [] $functionStats := nil $functorStats := nil $lisplibCategory := nil $lisplibAncestors := nil $lisplibAbbreviation := nil $CheckVectorList := [] $setelt := nil $pairlis := [] $functorTarget := nil $condAlist := [] $uncondAlist := [] $NRTslot1PredicateList := [] $NRTattributeAlist := [] $NRTslot1Info := nil $NRTdeltaListComp := [] $template := nil $signature := nil $isOpPackageName := false $lookupFunction := nil $byteAddress := nil $byteVec := nil $lisplibSlot1 := nil $sigAlist := [] $predAlist := [] $argumentConditionList := [] $finalEnv := nil $initCapsuleErrorCount := nil $CapsuleModemapFrame := nil $CapsuleDomainsInScope := nil $signatureOfForm := nil $addFormLhs := nil $lisplibSuperDomain := nil $sigList := [] $atList := [] ++ List of declarations appearing as side conditions of a where-expression. $whereDecls := nil ++ True if the current functor definition refines a domain. $subdomain := false --% compDefineAddSignature: (%Form,%Signature,%Env) -> %Env DomainSubstitutionFunction: (%List,%Form) -> %Form --% Subdomains ++ We are defining a functor with head given by `form', as a subdomain ++ of the domain designated by the domain form `super', and predicate ++ `pred' (a VM instruction form). Emit appropriate info into the ++ databases. emitSubdomainInfo(form,super,pred) == pred := eqSubst($AtVariables,form.args,pred) super := eqSubst($AtVariables,form.args,super) evalAndRwriteLispForm("evalOnLoad2",["noteSubDomainInfo", quoteForm form.op,quoteForm super, quoteForm pred]) ++ List of operations defined in a given capsule ++ Each item on this list is of the form ++ (op sig pred) ++ where ++ op: name of the operation ++ sig: signature of the operation ++ pred: scope predicate of the operation. $capsuleFunctions := nil ++ record that the operation `op' with signature `sig' and predicate ++ `pred' is defined in the current capsule of the current domain ++ being compiled. noteCapsuleFunctionDefinition(op,sig,pred) == member([op,sig,pred],$capsuleFunctions) => stackAndThrow('"redefinition of %1b: %2 %3", [op,formatUnabbreviated ["Mapping",:sig],formatIf pred]) $capsuleFunctions := [[op,sig,pred],:$capsuleFunctions] ++ Clear the list of functions defined in the last domain capsule. clearCapsuleFunctionTable() == $capsuleFunctions := nil ++ List of exports (paireed with scope predicate) declared in ++ the category of the currend domain or package. ++ Note: for category packages, this list is nil. $exports := nil noteExport(form,pred) == -- don't recheck category package exports; we just check -- them when defining the category. Plus, we might actually -- get indirect duplicates, which is OK. $insideCategoryPackageIfTrue => nil member([form,pred],$exports) => stackAndThrow('"redeclaration of %1 %2", [form,formatIf pred]) $exports := [[form,pred],:$exports] clearExportsTable() == $exports := nil makePredicate l == null l => true MKPF(l,"and") --% FUNCTIONS WHICH MUNCH ON == STATEMENTS ++ List of reserved identifiers for which the compiler has special ++ meanings and that shall not be redefined. $reservedNames == '(per rep _$) ++ Check that `var' (a variable of parameter name) is not a reversed name. checkVariableName var == MEMQ(var,$reservedNames) => stackAndThrow('"You cannot use reserved name %1b as variable",[var]) var checkParameterNames parms == for p in parms repeat checkVariableName p compDefine(form,m,e) == $macroIfTrue: local := false compDefine1(form,m,e) ++ We are about to process the body of a capsule. Check the form of ++ `Rep' definition, and whether it is appropriate to activate the ++ implicitly generated morphisms ++ per: Rep -> % ++ rep: % -> Rep ++ as local inline functions. checkRepresentation: (%Form,%List,%Env) -> %Env checkRepresentation(addForm,body,env) == domainRep := nil hasAssignRep := false -- assume code does not assign to Rep. viewFuns := nil null body => env -- Don't be too hard on nothing. -- Locate possible Rep definition for [stmt,:.] in tails body repeat stmt is ["%LET","Rep",val] => domainRep ~= nil => stackAndThrow('"You cannot assign to constant domain %1b",["Rep"]) if addForm = val then stackWarning('"OpenAxiom suggests removing assignment to %1b",["Rep"]) else if addForm ~= nil then stackWarning('"%1b differs from the base domain",["Rep"]) return hasAssignRep := true stmt is ["MDEF",["Rep",:.],:.] => stackWarning('"Consider using == definition for %1b",["Rep"]) return hasAssignRep := true stmt is ["IF",.,:l] or stmt is ["SEQ",:l] or stmt is ["exit",:l] => checkRepresentation(nil,l,env) stmt isnt ["DEF",[op,:args],sig,.,val] => nil -- skip for now. op in '(rep per) => domainRep ~= nil => stackAndThrow('"You cannot define implicitly generated %1b",[op]) viewFuns := [op,:viewFuns] op ~= "Rep" => nil -- we are only interested in Rep definition domainRep := val viewFuns ~= nil => stackAndThrow('"You cannot define both %1b and %2b",["Rep",:viewFuns]) -- A package has no "%". $functorKind = "package" => stackAndThrow('"You cannot define %1b in a package",["Rep"]) -- It is a mistake to define Rep in category defaults $insideCategoryPackageIfTrue => stackAndThrow('"You cannot define %1b in category defaults",["Rep"]) if args ~= nil then stackAndThrow('"%1b does take arguments",["Rep"]) if sig.target ~= nil then stackAndThrow('"You cannot specify type for %1b",["Rep"]) -- Now, trick the rest of the compiler into believing that -- `Rep' was defined the Old Way, for lookup purpose. stmt.op := "%LET" stmt.rest := ["Rep",domainRep] $useRepresentationHack := false -- Don't confuse `Rep' and `%'. -- Shall we perform the dirty tricks? if hasAssignRep then $useRepresentationHack := true -- Domain extensions with no explicit Rep definition have the -- the base domain as representation (at least operationally). else if null domainRep and addForm ~= nil then if $functorKind = "domain" and addForm isnt ["%Comma",:.] then domainRep := addForm is ["SubDomain",dom,.] => $subdomain := true dom addForm $useRepresentationHack := false env := putMacro('Rep,domainRep,env) env compDefine1: (%Form,%Mode,%Env) -> %Maybe %Triple compDefine1(form,m,e) == $insideExpressionIfTrue: local:= false --1. decompose after macro-expanding form ['DEF,lhs,signature,specialCases,rhs]:= form:= macroExpand(form,e) $insideWhereIfTrue and isMacro(form,e) and (m=$EmptyMode or m=$NoValueMode) => [lhs,m,putMacro(lhs.op,rhs,e)] checkParameterNames lhs.args null signature.target and not MEMQ(KAR rhs,$BuiltinConstructorNames) and (sig:= getSignatureFromMode(lhs,e)) => -- here signature of lhs is determined by a previous declaration compDefine1(['DEF,lhs,[sig.target,:signature.source],specialCases,rhs],m,e) if signature.target=$Category then $insideCategoryIfTrue:= true -- RDJ (11/83): when argument and return types are all declared, -- or arguments have types declared in the environment, -- and there is no existing modemap for this signature, add -- the modemap by a declaration, then strip off declarations and recurse e := compDefineAddSignature(lhs,signature,e) -- 2. if signature list for arguments is not empty, replace ('DEF,..) by -- ('where,('DEF,..),..) with an empty signature list; -- otherwise, fill in all NILs in the signature or/[x ~= nil for x in signature.source] => compDefWhereClause(form,m,e) signature.target=$Category => compDefineCategory(form,m,e,nil,$formalArgList) isDomainForm(rhs,e) and not $insideFunctorIfTrue => if null signature.target then signature:= [getTargetFromRhs(lhs,rhs,giveFormalParametersValues(lhs.args,e)),: signature.source] rhs:= addEmptyCapsuleIfNecessary(signature.target,rhs) compDefineFunctor(['DEF,lhs,signature,specialCases,rhs],m,e,nil, $formalArgList) null $form => stackAndThrow ['"bad == form ",form] newPrefix:= $prefix => INTERN strconc(encodeItem $prefix,'",",encodeItem $op) getConstructorAbbreviationFromDB $op compDefineCapsuleFunction(form,m,e,newPrefix,$formalArgList) compDefineAddSignature([op,:argl],signature,e) == (sig:= hasFullSignature(argl,signature,e)) and not assoc(['$,:sig],LASSOC('modemap,getProplist(op,e))) => declForm:= [":",[op,:[[":",x,m] for x in argl for m in sig.source]],signature.target] [.,.,e]:= comp(declForm,$EmptyMode,e) e e hasFullSignature(argl,[target,:ml],e) == target => u:= [m or get(x,"mode",e) or return 'failed for x in argl for m in ml] u~='failed => [target,:u] addEmptyCapsuleIfNecessary: (%Form,%Form) -> %Form addEmptyCapsuleIfNecessary(target,rhs) == MEMQ(KAR rhs,$SpecialDomainNames) => rhs ['add,rhs,['CAPSULE]] getTargetFromRhs: (%Form, %Form, %Env) -> %Form getTargetFromRhs(lhs,rhs,e) == --undeclared target mode obtained from rhs expression rhs is ['CAPSULE,:.] => stackSemanticError(['"target category of ",lhs, '" cannot be determined from definition"],nil) rhs is ['SubDomain,D,:.] => getTargetFromRhs(lhs,D,e) rhs is ['add,D,['CAPSULE,:.]] => getTargetFromRhs(lhs,D,e) rhs is ['Record,:l] => ['RecordCategory,:l] rhs is ['Union,:l] => ['UnionCategory,:l] (compOrCroak(rhs,$EmptyMode,e)).mode giveFormalParametersValues(argl,e) == for x in argl | IDENTP x repeat e := giveVariableSomeValue(x,get(x,'mode,e),e) e macroExpandInPlace: (%Form,%Env) -> %Form macroExpandInPlace(x,e) == y:= macroExpand(x,e) atom x or atom y => y x.first := first y x.rest := rest y x macroExpand: (%Form,%Env) -> %Form macroExpand(x,e) == --not worked out yet atom x => not IDENTP x or (u := get(x,'macro,e)) = nil => x -- Don't expand a functional macro name by itself. u is ['%mlambda,:.] => x macroExpand(u,e) x is ['DEF,lhs,sig,spCases,rhs] => ['DEF,macroExpand(lhs,e),macroExpandList(sig,e),macroExpandList(spCases,e), macroExpand(rhs,e)] -- macros should override niladic props [op,:args] := x IDENTP op and args = nil and niladicConstructorFromDB op and (u := get(op,'macro, e)) => macroExpand(u,e) IDENTP op and (get(op,'macro,e) is ['%mlambda,parms,body]) => nargs := #args nparms := #parms msg := nargs < nparms => '"Too few arguments" nargs > nparms => '"Too many arguments" nil msg => (stackMessage(strconc(msg,'" to macro %1bp"),[op]); x) args' := macroExpandList(args,e) SUBLISLIS(args',parms,body) macroExpandList(x,e) macroExpandList(l,e) == [macroExpand(x,e) for x in l] --% constructor evaluation mkEvalableCategoryForm c == c is [op,:argl] => op="Join" => ["Join",:[mkEvalableCategoryForm x for x in argl]] op is "DomainSubstitutionMacro" => mkEvalableCategoryForm second argl op is "mkCategory" => c MEMQ(op,$CategoryNames) => ([x,m,$e]:= compOrCroak(c,$EmptyMode,$e); m=$Category => x) --loadIfNecessary op getConstructorKindFromDB op = 'category or get(op,"isCategory",$CategoryFrame) => [op,:[MKQ x for x in argl]] [x,m,$e]:= compOrCroak(c,$EmptyMode,$e) m=$Category => x MKQ c ++ Return true if we should skip compilation of category package. ++ This situation happens either when there is no default, of we are in ++ bootstrap mode, or we are compiling only for exports. skipCategoryPackage? capsule == null capsule or $bootStrapMode or $compileExportsOnly compDefineCategory1(df is ['DEF,form,sig,sc,body],m,e,prefix,fal) == categoryCapsule := body is ['add,cat,capsule] => body := cat capsule nil [d,m,e]:= compDefineCategory2(form,sig,sc,body,m,e,prefix,fal) if not skipCategoryPackage? categoryCapsule then [.,.,e] := $insideCategoryPackageIfTrue: local := true $categoryPredicateList: local := makeCategoryPredicates(form,$lisplibCategory) T := compDefine1(mkCategoryPackage(form,cat,categoryCapsule),$EmptyMode,e) or return stackSemanticError( ['"cannot compile defaults of",:bright opOf form],nil) if $compileDefaultsOnly then [d,m,e] := T [d,m,e] makeCategoryPredicates(form,u) == $tvl: local := TAKE(#rest form,$TriangleVariableList) $mvl: local := TAKE(#rest form,rest $FormalMapVariableList) fn(u,nil) where fn(u,pl) == u is ['Join,:.,a] => fn(a,pl) u is ["IF",p,:x] => fnl(x,insert(EQSUBSTLIST($mvl,$tvl,p),pl)) u is ["has",:.] => insert(EQSUBSTLIST($mvl,$tvl,u),pl) u is [op,:.] and op in '(SIGNATURE ATTRIBUTE) => pl atom u => pl fnl(u,pl) fnl(u,pl) == for x in u repeat pl := fn(x,pl) pl mkCategoryPackage(form is [op,:argl],cat,def) == packageName:= INTERN(strconc(PNAME op,'"&")) packageAbb := INTERN(strconc(getConstructorAbbreviationFromDB op,'"-")) $options:local := [] -- This stops the next line from becoming confused abbreviationsSpad2Cmd ['domain,packageAbb,packageName] -- This is a little odd, but the parser insists on calling -- domains, rather than packages nameForDollar := first SETDIFFERENCE('(S A B C D E F G H I),argl) packageArgl := [nameForDollar,:argl] capsuleDefAlist := fn(def,nil) where fn(x,oplist) == atom x => oplist x is ['DEF,y,:.] => [y,:oplist] fn(x.args,fn(x.op,oplist)) catvec := eval mkEvalableCategoryForm form fullCatOpList:=(JoinInner([catvec],$e)).1 catOpList := [['SIGNATURE,op1,sig] for [[op1,sig],:.] in fullCatOpList | assoc(op1,capsuleDefAlist)] null catOpList => nil packageCategory := ['CATEGORY,'domain, :SUBLISLIS(argl,$FormalMapVariableList,catOpList)] nils:= [nil for x in argl] packageSig := [packageCategory,form,:nils] $categoryPredicateList := substitute(nameForDollar,'$,$categoryPredicateList) substitute(nameForDollar,'$, ['DEF,[packageName,:packageArgl],packageSig,[nil,:nils],def]) compDefineCategory2(form,signature,specialCases,body,m,e, $prefix,$formalArgList) == --1. bind global variables $insideCategoryIfTrue: local:= true $definition: local := form --used by DomainSubstitutionFunction $form: local := nil $op: local := nil $extraParms: local := nil -- Remember the body for checking the current instantiation. $currentCategoryBody : local := body --Set in DomainSubstitutionFunction, used further down -- 1.1 augment e to add declaration $:
[$op,:argl] := $definition e:= addBinding("$",[['mode,:$definition]],e) -- 2. obtain signature signature':= [signature.target, :[getArgumentModeOrMoan(a,$definition,e) for a in argl]] e:= giveFormalParametersValues(argl,e) -- 3. replace arguments by $1,..., substitute into body, -- and introduce declarations into environment sargl:= TAKE(# argl, $TriangleVariableList) $functorForm:= $form:= [$op,:sargl] $formalArgList:= [:sargl,:$formalArgList] aList := pairList(argl,sargl) formalBody:= SUBLIS(aList,body) signature' := SUBLIS(aList,signature') --Begin lines for category default definitions $functionStats: local:= [0,0] $functorStats: local:= [0,0] $getDomainCode: local := nil $addForm: local:= nil for x in sargl for t in signature'.source repeat [.,.,e]:= compMakeDeclaration(x,t,e) -- 4. compile body in environment of %type declarations for arguments op':= $op -- following line causes cats with no with or Join to be fresh copies if opOf(formalBody)~='Join and opOf(formalBody)~='mkCategory then formalBody := ['Join, formalBody] body:= optFunctorBody compOrCroak(formalBody,signature'.target,e).expr if $extraParms then formals:=actuals:=nil for u in $extraParms repeat formals:=[first u,:formals] actuals:=[MKQ rest u,:actuals] body := ['sublisV,['PAIR,['QUOTE,formals],['LIST,:actuals]],body] if argl then body:= -- always subst for args after extraparms ['sublisV,['PAIR,['QUOTE,sargl],['LIST,: [['devaluate,u] for u in sargl]]],body] body:= ["%bind",[[g:= gensym(),body]], ["setShellEntry",g,0,mkConstructor $form],g] fun:= compile [op',["LAM",sargl,body]] -- 5. give operator a 'modemap property pairlis := pairList(argl,$FormalMapVariableList) parSignature:= SUBLIS(pairlis,signature') parForm:= SUBLIS(pairlis,form) -- If we are only interested in the defaults, there is no point -- in writing out compiler info and load-time stuff for -- the category which is assumed to have already been translated. if not $compileDefaultsOnly then lisplibWrite('"compilerInfo", removeZeroOne ['SETQ,'$CategoryFrame, ['put,['QUOTE,op'],' (QUOTE isCategory),true,['addModemap,MKQ op',MKQ parForm, MKQ parSignature,true,MKQ fun,'$CategoryFrame]]],$libFile) --Equivalent to the following two lines, we hope if null sargl then evalAndRwriteLispForm('NILADIC, ['MAKEPROP,['QUOTE,op'],'(QUOTE NILADIC),true]) -- 6. put modemaps into InteractiveModemapFrame $domainShell := eval [op',:MAPCAR('MKQ,sargl)] $lisplibCategory:= formalBody if $LISPLIB then $lisplibForm:= form $lisplibKind:= 'category modemap:= [[parForm,:parSignature],[true,op']] $lisplibModemap:= modemap $lisplibParents := getParentsFor($op,$FormalMapVariableList,$lisplibCategory) $lisplibAncestors := computeAncestorsOf($form,nil) $lisplibAbbreviation := constructor? $op form':=[op',:sargl] augLisplibModemapsFromCategory(form',formalBody,signature') [fun,$Category,e] mkConstructor: %Form -> %Form mkConstructor form == atom form => ['devaluate,form] null form.args => ['QUOTE,[form.op]] ['LIST,MKQ form.op,:[mkConstructor x for x in form.args]] compDefineCategory(df,m,e,prefix,fal) == $domainShell: local := nil -- holds the category of the object being compiled $lisplibCategory: local := nil -- since we have so many ways to say state the kind of a constructor, -- make sure we do have some minimal internal coherence. ctor := opOf second df kind := getConstructorKindFromDB ctor kind ~= "category" => throwKeyedMsg("S2IC0016",[ctor,"category",kind]) $insideFunctorIfTrue or not $LISPLIB or $compileDefaultsOnly => compDefineCategory1(df,m,e,prefix,fal) compDefineLisplib(df,m,e,prefix,fal,'compDefineCategory1) %CatObjRes -- result of compiling a category <=> [%Shell,:[%Mode,:[%Env,:null]]] compMakeCategoryObject: (%Form,%Env) -> %Maybe %CatObjRes compMakeCategoryObject(c,$e) == not isCategoryForm(c,$e) => nil u:= mkEvalableCategoryForm c => [eval u,$Category,$e] nil predicatesFromAttributes: %List -> %List predicatesFromAttributes attrList == removeDuplicates [second x for x in attrList] ++ Subroutine of inferConstructorImplicitParameters. typeDependencyPath(m,path,e) == IDENTP m and assoc(m,$whereDecls) => get(m,'value,e) => nil -- parameter was given value [[m,:reverse path],:typeDependencyPath(getmode(m,e),path,e)] isAtomicForm m => nil [ctor,:args] := m -- We don't expect implicit parameters in builtin constructors. ctor in $BuiltinConstructorNames => nil -- FIXME: assume constructors cannot be parameters not constructor? ctor => nil [:typeDependencyPath(m',[i,:path],e) for m' in args for i in 0..] ++ Given the list `parms' of explicit constructor parameters, compute ++ a list of pairs `(p . path)' where `p' is a parameter implicitly ++ introduced (either directly or indirectly) by a declaration of ++ one of the explicit parameters. inferConstructorImplicitParameters(parms,e) == removeDuplicates [:typeDependencyPath(getmode(p,e),[i],e) for p in parms for i in 0..] compDefineFunctor(df,m,e,prefix,fal) == $domainShell: local := nil -- holds the category of the object being compiled $profileCompiler: local := true $profileAlist: local := nil $mutableDomain: fluid := false $compileExportsOnly or not $LISPLIB => compDefineFunctor1(df,m,e,prefix,fal) compDefineLisplib(df,m,e,prefix,fal,'compDefineFunctor1) compDefineFunctor1(df is ['DEF,form,signature,nils,body], m,$e,$prefix,$formalArgList) == -- 1. bind global variables $addForm: local := nil $subdomain: local := false $functionStats: local:= [0,0] $functorStats: local:= [0,0] $form: local := nil $op: local := nil $signature: local := nil $functorTarget: local := nil $Representation: local := nil --Set in doIt, accessed in the compiler - compNoStacking $functorForm: local := nil $functorLocalParameters: local := nil $CheckVectorList: local := nil $getDomainCode: local := nil -- code for getting views $insideFunctorIfTrue: local:= true $setelt: local := "setShellEntry" $genSDVar: local:= 0 originale:= $e [$op,:argl]:= form $formalArgList:= [:argl,:$formalArgList] $pairlis: local := pairList(argl,$FormalMapVariableList) $mutableDomain: local := -- all defaulting packages should have caching turned off isCategoryPackageName $op or MEMQ($op,$mutableDomains) --true if domain has mutable state signature':= [signature.target,:[getArgumentModeOrMoan(a,form,$e) for a in argl]] $functorForm := $form := [$op,:argl] if null signature'.target then signature':= modemap2Signature getModemap($form,$e) $functorTarget := target := signature'.target $functorKind: local := $functorTarget is ["CATEGORY",key,:.] => key "domain" $e := giveFormalParametersValues(argl,$e) $implicitParameters: local := inferConstructorImplicitParameters(argl,$e) [ds,.,$e]:= compMakeCategoryObject(target,$e) or return stackAndThrow('" cannot produce category object: %1pb",[target]) $compileExportsOnly => compDefineExports(form, ds.1, signature',$e) $domainShell: local := COPY_-SEQ ds attributeList := ds.2 --see below under "loadTimeAlist" $condAlist: local := nil $uncondAlist: local := nil $NRTslot1PredicateList: local := predicatesFromAttributes attributeList $NRTattributeAlist: local := NRTgenInitialAttributeAlist attributeList $NRTslot1Info: local := nil --set in NRTmakeSlot1Info --this is used below to set $lisplibSlot1 global $NRTaddForm: local := nil -- see compAdd $NRTdeltaList: local := nil --list of misc. elts used in compiled fncts $NRTdeltaListComp: local := nil --list of compiled forms for $NRTdeltaList $NRTdeltaLength: local := 0 -- =length of block of extra entries in vector $template: local:= nil --stored in the lisplib $functionLocations: local := nil --locations of defined functions in source -- generate slots for arguments first, then for $NRTaddForm in compAdd for x in argl repeat NRTgetLocalIndex x [.,.,$e]:= compMakeDeclaration("$",target,$e) if not $insideCategoryPackageIfTrue then $e:= augModemapsFromCategory('_$,'_$,'_$,target,$e) $signature:= signature' parSignature:= SUBLIS($pairlis,signature') parForm:= SUBLIS($pairlis,form) -- (3.1) now make a list of the functor's local parameters; for -- domain D in argl,check its signature: if domain, its type is Join(A1,..,An); -- in this case, D is replaced by D1,..,Dn (gensyms) which are set -- to the A1,..,An view of D makeFunctorArgumentParameters(argl,signature'.source,signature'.target) $functorLocalParameters := argl -- 4. compile body in environment of %type declarations for arguments op':= $op rettype:= signature'.target -- If this functor is defined as instantiation of a functor -- that is a subdomain of `D', then make this functor also a subdomain -- of that super domain `D'. if body is ["add",[rhsCtor,:rhsArgs],["CAPSULE"]] and constructor? rhsCtor and (u := getSuperDomainFromDB rhsCtor) then u := sublisFormal(rhsArgs,u,$AtVariables) emitSubdomainInfo($form,first u, second u) T:= compFunctorBody(body,rettype,$e,parForm) -- If only compiling certain items, then ignore the body shell. $compileOnlyCertainItems => reportOnFunctorCompilation() [nil, ['Mapping, :signature'], originale] body':= T.expr lamOrSlam:= if $mutableDomain then 'LAM else 'SPADSLAM fun:= compile SUBLIS($pairlis, [op',[lamOrSlam,argl,body']]) --The above statement stops substitutions gettting in one another's way operationAlist := SUBLIS($pairlis,$lisplibOperationAlist) if $LISPLIB then augmentLisplibModemapsFromFunctor(parForm,operationAlist,parSignature) reportOnFunctorCompilation() -- 5. give operator a 'modemap property if $LISPLIB then modemap:= [[parForm,:parSignature],[true,op']] $lisplibModemap:= modemap $lisplibCategory := modemap.mmTarget $lisplibParents := getParentsFor($op,$FormalMapVariableList,$lisplibCategory) $lisplibAncestors := computeAncestorsOf($form,nil) $lisplibAbbreviation := constructor? $op $insideFunctorIfTrue:= false if $LISPLIB then $lisplibKind:= $functorTarget is ["CATEGORY",key,:.] and key~="domain" => 'package 'domain $lisplibForm:= form if null $bootStrapMode then $NRTslot1Info := NRTmakeSlot1Info() $isOpPackageName: local := isCategoryPackageName $op if $isOpPackageName then lisplibWrite('"slot1DataBase", ['updateSlot1DataBase,MKQ $NRTslot1Info],$libFile) $lisplibFunctionLocations := SUBLIS($pairlis,$functionLocations) libFn := getConstructorAbbreviationFromDB op' $lookupFunction: local := NRTgetLookupFunction($functorForm,$lisplibModemap.mmTarget,$NRTaddForm) --either lookupComplete (for forgetful guys) or lookupIncomplete $byteAddress :local := 0 $byteVec :local := nil $NRTslot1PredicateList := [simpBool x for x in $NRTslot1PredicateList] rwriteLispForm('loadTimeStuff, ['MAKEPROP,MKQ $op,''infovec,getInfovecCode()]) $lisplibSlot1 := $NRTslot1Info $lisplibOperationAlist:= operationAlist lisplibWrite('"compilerInfo", removeZeroOne ['SETQ,'$CategoryFrame, ['put,['QUOTE,op'],' (QUOTE isFunctor), ['QUOTE,operationAlist],['addModemap,['QUOTE,op'],[' QUOTE,parForm],['QUOTE,parSignature],true,['QUOTE,op'], ['put,['QUOTE,op' ],'(QUOTE mode), ['QUOTE,['Mapping,:parSignature]],'$CategoryFrame]]]],$libFile) if null argl then evalAndRwriteLispForm('NILADIC, ['MAKEPROP, ['QUOTE,op'], ['QUOTE,'NILADIC], true]) [fun,['Mapping,:signature'],originale] ++ Subroutine of compDefineFunctor1. Called to generate backend code ++ for a functor definition. compFunctorBody(body,m,e,parForm) == $bootStrapMode = true => [bootStrapError($functorForm, _/EDITFILE),m,e] clearCapsuleDirectory() -- start collecting capsule functions. T:= compOrCroak(body,m,e) $capsuleFunctionStack := nreverse $capsuleFunctionStack -- ??? Don't resolve default definitions, yet. if $insideCategoryPackageIfTrue then backendCompile $capsuleFunctionStack else backendCompile foldExportedFunctionReferences $capsuleFunctionStack clearCapsuleDirectory() -- release storage. body is [op,:.] and op in '(add CAPSULE) => T $NRTaddForm := body is ["SubDomain",domainForm,predicate] => domainForm body T reportOnFunctorCompilation() == displayMissingFunctions() if $semanticErrorStack then sayBrightly '" " displaySemanticErrors() if $warningStack then sayBrightly '" " displayWarnings() $functorStats:= addStats($functorStats,$functionStats) [byteCount,elapsedSeconds] := $functorStats sayBrightly ['%l,:bright '" Cumulative Statistics for Constructor", $op] timeString := normalizeStatAndStringify elapsedSeconds sayBrightly ['" Time:",:bright timeString,'"seconds"] sayBrightly '" " 'done displayMissingFunctions() == null $CheckVectorList => nil loc := nil -- list of local operation signatures exp := nil -- list of exported operation signatures for [[op,sig,:.],:pred] in $CheckVectorList | null pred repeat not member(op,$formalArgList) and getmode(op,$e) is ['Mapping,:.] => loc := [[op,sig],:loc] exp := [[op,sig],:exp] if loc then sayBrightly ['%l,:bright '" Missing Local Functions:"] for [op,sig] in loc for i in 1.. repeat sayBrightly ['" [",i,'"]",:bright op, ": ",:formatUnabbreviatedSig sig] if exp then sayBrightly ['%l,:bright '" Missing Exported Functions:"] for [op,sig] in exp for i in 1.. repeat sayBrightly ['" [",i,'"]",:bright op, ": ",:formatUnabbreviatedSig sig] --% domain view code makeFunctorArgumentParameters(argl,sigl,target) == $forceAdd: local:= true $ConditionalOperators: local := nil ("append"/[fn(a,augmentSig(s,findExtras(a,target))) for a in argl for s in sigl]) where findExtras(a,target) == -- see if conditional information implies anything else -- in the signature of a target is ['Join,:l] => "union"/[findExtras(a,x) for x in l] target is ['CATEGORY,.,:l] => "union"/[findExtras1(a,x) for x in l] where findExtras1(a,x) == x is ['AND,:l] => "union"/[findExtras1(a,y) for y in l] x is ['OR,:l] => "union"/[findExtras1(a,y) for y in l] x is ['IF,c,p,q] => union(findExtrasP(a,c), union(findExtras1(a,p),findExtras1(a,q))) where findExtrasP(a,x) == x is ['AND,:l] => "union"/[findExtrasP(a,y) for y in l] x is ['OR,:l] => "union"/[findExtrasP(a,y) for y in l] x is ["has",=a,y] and y is ['SIGNATURE,:.] => [y] nil nil augmentSig(s,ss) == -- if we find something extra, add it to the signature null ss => s for u in ss repeat $ConditionalOperators:=[rest u,:$ConditionalOperators] s is ['Join,:sl] => u:=ASSQ('CATEGORY,ss) => MSUBST([:u,:ss],u,s) ['Join,:sl,['CATEGORY,'package,:ss]] ['Join,s,['CATEGORY,'package,:ss]] fn(a,s) == isCategoryForm(s,$CategoryFrame) => s is ["Join",:catlist] => genDomainViewList(a,s.args) [genDomainView(a,a,s,"getDomainView")] [a] genDomainOps(viewName,dom,cat) == oplist:= getOperationAlist(dom,dom,cat) siglist:= [sig for [sig,:.] in oplist] oplist:= substNames(dom,viewName,dom,oplist) cd:= ["%LET",viewName,['mkOpVec,dom,['LIST,: [['LIST,MKQ op,['LIST,:[mkTypeForm mode for mode in sig]]] for [op,sig] in siglist]]]] $getDomainCode:= [cd,:$getDomainCode] for [opsig,cond,:.] in oplist for i in 0.. repeat if member(opsig,$ConditionalOperators) then cond:=nil [op,sig]:=opsig $e:= addModemap(op,dom,sig,cond,['ELT,viewName,i],$e) viewName genDomainView(viewName,originalName,c,viewSelector) == c is ['CATEGORY,.,:l] => genDomainOps(viewName,originalName,c) code:= c is ['SubsetCategory,c',.] => c' c $e:= augModemapsFromCategory(originalName,viewName,nil,c,$e) cd:= ["%LET",viewName,[viewSelector,originalName,mkTypeForm code]] if null member(cd,$getDomainCode) then $getDomainCode:= [cd,:$getDomainCode] viewName genDomainViewList: (%Symbol,%List) -> %List genDomainViewList(id,catlist) == [genDomainView(id,id,cat,"getDomainView") for cat in catlist | isCategoryForm(cat,$EmptyEnvironment)] mkOpVec(dom,siglist) == dom:= getPrincipalView dom substargs:= [['$,:dom.0],:pairList($FormalMapVariableList,rest dom.0)] oplist:= getOperationAlistFromLisplib opOf dom.0 --new form is ( ) ops:= MAKE_-VEC (#siglist) for (opSig:= [op,sig]) in siglist for i in 0.. repeat u:= ASSQ(op,oplist) assoc(sig,u) is [.,n,.,'ELT] => ops.i := dom.n noplist:= SUBLIS(substargs,u) -- following variation on assoc needed for GENSYMS in Mutable domains AssocBarGensym(substitute(dom.0,'$,sig),noplist) is [.,n,.,'ELT] => ops.i := dom.n ops.i := [function Undef,[dom.0,i],:opSig] ops ++ form is lhs (f a1 ... an) of definition; body is rhs; ++ signature is (t0 t1 ... tn) where t0= target type, ti=type of ai, i > 0; ++ specialCases is (NIL l1 ... ln) where li is list of special cases ++ which can be given for each ti ++ removes declarative and assignment information from form and ++ signature, placing it in list L, replacing form by ("where",form',:L), ++ signature by a list of NILs (signifying declarations are in e) compDefWhereClause(['DEF,form,signature,specialCases,body],m,e) == $sigAlist: local := nil $predAlist: local := nil -- 1. create sigList= list of all signatures which have embedded -- declarations moved into global variable $sigAlist sigList:= [transformType fetchType(a,x,e,form) for a in form.args for x in signature.source] where fetchType(a,x,e,form) == x => x getmode(a,e) or userError concat( '"There is no mode for argument",a,'"of function",form.op) transformType x == atom x => x x is [":",R,Rtype] => ($sigAlist:= [[R,:transformType Rtype],:$sigAlist]; x) x is ['Record,:.] => x --RDJ 8/83 [x.op,:[transformType y for y in x.args]] -- 2. replace each argument of the form (|| x p) by x, recording -- the given predicate in global variable $predAlist argList:= [removeSuchthat a for a in form.args] where removeSuchthat x == x is ["|",y,p] => ($predAlist:= [[y,:p],:$predAlist]; y) x -- 3. obtain a list of parameter identifiers (x1 .. xn) ordered so that -- the type of xi is independent of xj if i < j varList := orderByDependency(ASSOCLEFT argDepAlist,ASSOCRIGHT argDepAlist) where argDepAlist := [[x,:dependencies] for [x,:y] in argSigAlist] where dependencies() == union(listOfIdentifiersIn y, delete(x,listOfIdentifiersIn LASSOC(x,$predAlist))) argSigAlist := [:$sigAlist,:pairList(argList,sigList)] -- 4. construct a WhereList which declares and/or defines the xi's in -- the order constructed in step 3 whereList := [addSuchthat(x,[":",x,LASSOC(x,argSigAlist)]) for x in varList] where addSuchthat(x,y) == p := LASSOC(x,$predAlist) => ["|",y,p] y -- 5. compile new ('DEF,("where",form',:WhereList),:.) where -- all argument parameters of form' are bound/declared in WhereList comp(form',m,e) where form' := ["where",defform,:whereList] where defform := ['DEF,form'',signature',specialCases,body] where form'' := [form.op,:argList] signature' := [signature.target,:[nil for x in signature.source]] orderByDependency(vl,dl) == -- vl is list of variables, dl is list of dependency-lists selfDependents:= [v for v in vl for d in dl | MEMQ(v,d)] for v in vl for d in dl | MEMQ(v,d) repeat (SAY(v," depends on itself"); fatalError:= true) fatalError => userError '"Parameter specification error" until (null vl) repeat newl:= [v for v in vl for d in dl | null intersection(d,vl)] or return nil orderedVarList:= [:newl,:orderedVarList] vl':= setDifference(vl,newl) dl':= [setDifference(d,newl) for x in vl for d in dl | member(x,vl')] vl:= vl' dl:= dl' removeDuplicates nreverse orderedVarList --ordered so ith is indep. of jth if i < j compDefineCapsuleFunction(df is ['DEF,form,signature,specialCases,body], m,$e,$prefix,$formalArgList) == [lineNumber,:specialCases] := specialCases e := $e --1. bind global variables $form: local := nil $op: local := nil $functionStats: local:= [0,0] $argumentConditionList: local := nil $finalEnv: local := nil --used by ReplaceExitEtc to get a common environment $initCapsuleErrorCount: local:= #$semanticErrorStack $insideCapsuleFunctionIfTrue: local:= true $CapsuleModemapFrame: local:= e $CapsuleDomainsInScope: local:= get("$DomainsInScope","special",e) $insideExpressionIfTrue: local:= true $returnMode:= m -- Change "^" to "**" in definitions. All other places have -- been changed before we get here. if form.op = "^" then sayBrightly ['"Replacing", :bright '"^", '"with",:bright '"**"] form.op := "**" [$op,:argl]:= form $form:= [$op,:argl] argl:= stripOffArgumentConditions argl $formalArgList:= [:argl,:$formalArgList] --let target and local signatures help determine modes of arguments argModeList := identSig := hasSigInTargetCategory(argl,form,signature.target,e) => (e:= checkAndDeclare(argl,form,identSig,e); identSig.source) [getArgumentModeOrMoan(a,form,e) for a in argl] argModeList := stripOffSubdomainConditions(argModeList,argl) signature' := [signature.target,:argModeList] if null identSig then --make $op a local function $e := put($op,'mode,['Mapping,:signature'],$e) --obtain target type if not given if null signature'.target then signature':= identSig => identSig getSignature($op,signature'.source,e) or return nil e:= giveFormalParametersValues(argl,e) $signatureOfForm:= signature' --this global is bound in compCapsuleItems $functionLocations := [[[$op,$signatureOfForm],:lineNumber], :$functionLocations] e:= addDomain(signature'.target,e) e:= compArgumentConditions e if $profileCompiler then for x in argl for t in signature'.source repeat profileRecord('arguments,x,t) --4. introduce needed domains into extendedEnv for domain in signature' repeat e:= addDomain(domain,e) --6. compile body in environment with extended environment rettype:= resolve(signature'.target,$returnMode) localOrExported := null member($op,$formalArgList) and getmode($op,e) is ['Mapping,:.] => 'local 'exported --6a skip if compiling only certain items but not this one -- could be moved closer to the top formattedSig := formatUnabbreviated ['Mapping,:signature'] $compileOnlyCertainItems and _ not member($op, $compileOnlyCertainItems) => sayBrightly ['" skipping ", localOrExported,:bright $op] [nil,['Mapping,:signature'],$e] sayBrightly ['" compiling ",localOrExported, :bright $op,'": ",:formattedSig] noteCapsuleFunctionDefinition($op,signature', makePredicate $predl) T := CATCH('compCapsuleBody, compOrCroak(body,rettype,e)) or [$ClearBodyToken,rettype,e] NRTassignCapsuleFunctionSlot($op,signature') if $newCompCompare=true then SAY '"The old compiler generates:" prTriple T -- A THROW to the above CATCH occurs if too many semantic errors occur -- see stackSemanticError catchTag:= MKQ gensym() fun:= body':= replaceExitEtc(T.expr,catchTag,"TAGGEDreturn",$returnMode) body':= addArgumentConditions(body',$op) finalBody:= ["CATCH",catchTag,body'] compile [$op,["LAM",[:argl,'_$],finalBody]] $functorStats:= addStats($functorStats,$functionStats) --7. give operator a 'value property val:= [fun,signature',e] [fun,['Mapping,:signature'],$e] getSignatureFromMode(form,e) == getmode(opOf form,e) is ['Mapping,:signature] => #form~=#signature => stackAndThrow ["Wrong number of arguments: ",form] EQSUBSTLIST(form.args,take(# form.args,$FormalMapVariableList),signature) candidateSignatures(op,nmodes,slot1) == [sig for [[=op,sig,:.],:.] in slot1 | #sig = nmodes] ++ We are compiling a capsule function definition with head given by `form'. ++ Determine whether the function with possibly partial signature `opsig' ++ is exported. Return the complete signature if yes; otherwise ++ return nil, with diagnostic in ambiguity case. hasSigInTargetCategory(argl,form,opsig,e) == sigs := candidateSignatures($op,#form,$domainShell.1) cc := checkCallingConvention(sigs,#argl) mList:= [(cc.i > 0 => quasiquote x; getArgumentMode(x,e)) for x in argl for i in 0..] --each element is a declared mode for the variable or nil if none exists potentialSigList:= removeDuplicates [sig for sig in sigs | fn(sig,opsig,mList)] where fn(sig,opsig,mList) == (null opsig or opsig=sig.target) and (and/[compareMode2Arg(x,m) for x in mList for m in sig.source]) c:= #potentialSigList 1=c => first potentialSigList --accept only those signatures op right length which match declared modes 0=c => (#(sig:= getSignatureFromMode(form,e))=#form => sig; nil) 1 ambiguousSignatureError($op,potentialSigList) first potentialSigList nil --this branch will force all arguments to be declared compareMode2Arg(x,m) == null x or modeEqual(x,m) getArgumentModeOrMoan: (%Form, %Form, %Env) -> %Mode getArgumentModeOrMoan(x,form,e) == getArgumentMode(x,e) or stackSemanticError(["argument ",x," of ",form," is not declared"],nil) getArgumentMode: (%Form,%Env) -> %Mode getArgumentMode(x,e) == string? x => x m:= get(x,'mode,e) => m checkAndDeclare(argl,form,sig,e) == -- arguments with declared types must agree with those in sig; -- those that don't get declarations put into e for a in argl for m in sig.source repeat isQuasiquote m => nil -- we just built m from a. m1:= getArgumentMode(a,e) => not modeEqual(m1,m) => stack:= [" ",:bright a,'"must have type ",m, '" not ",m1,'%l,:stack] e:= put(a,'mode,m,e) if stack then sayBrightly ['" Parameters of ",:bright form.op, '" are of wrong type:",'%l,:stack] e getSignature(op,argModeList,$e) == 1=# (sigl:= removeDuplicates [sig for [[dc,:sig],[pred,:.]] in (mmList:= get(op,'modemap,$e)) | dc='_$ and sig.source = argModeList and knownInfo pred]) => first sigl null sigl => (u:= getmode(op,$e)) is ['Mapping,:sig] => sig SAY '"************* USER ERROR **********" SAY("available signatures for ",op,": ") if null mmList then SAY " NONE" else for [[dc,:sig],:.] in mmList repeat printSignature(" ",op,sig) printSignature("NEED ",op,["?",:argModeList]) nil 1=#sigl => first sigl stackSemanticError(["duplicate signatures for ",op,": ",argModeList],nil) --% ARGUMENT CONDITION CODE stripOffArgumentConditions argl == [f for x in argl for i in 1..] where f() == x is ["|",arg,condition] => condition:= substitute('_#1,arg,condition) -- in case conditions are given in terms of argument names, replace $argumentConditionList:= [[i,arg,condition],:$argumentConditionList] arg x stripOffSubdomainConditions(margl,argl) == [f for x in margl for arg in argl for i in 1..] where f() == x is ['SubDomain,marg,condition] => pair:= assoc(i,$argumentConditionList) => (pair.rest.first := MKPF([condition,second pair],'AND); marg) $argumentConditionList:= [[i,arg,condition],:$argumentConditionList] marg x compArgumentConditions: %Env -> %Env compArgumentConditions e == $argumentConditionList:= [f for [n,a,x] in $argumentConditionList] where f() == y:= substitute(a,'_#1,x) T := [.,.,e]:= compOrCroak(y,$Boolean,e) [n,x,T.expr] e addArgumentConditions($body,$functionName) == $argumentConditionList => --$body is only used in this function fn $argumentConditionList where fn clist == clist is [[n,untypedCondition,typedCondition],:.] => ['COND,[typedCondition,fn rest clist], [$true,["argumentDataError",n, MKQ untypedCondition,MKQ $functionName]]] null clist => $body systemErrorHere ["addArgumentConditions",clist] $body putInLocalDomainReferences (def := [opName,[lam,varl,body]]) == $elt: local := "getShellEntry" NRTputInTail CDDADR def def $savableItems := nil compile u == [op,lamExpr] := u if $suffix then $suffix:= $suffix+1 op':= opexport:=nil opmodes:= [sel for [[DC,:sig],[.,sel]] in get(op,'modemap,$e) | DC='_$ and (opexport:=true) and (and/[modeEqual(x,y) for x in sig for y in $signatureOfForm])] isLocalFunction op => if opexport then userError ['%b,op,'%d,'" is local and exported"] INTERN strconc(encodeItem $prefix,'";",encodeItem op) encodeFunctionName(op,$functorForm,$signatureOfForm,";",$suffix) where isLocalFunction op == null member(op,$formalArgList) and getmode(op,$e) is ['Mapping,:.] u:= [op',lamExpr] -- If just updating certain functions, check for previous existence. -- Deduce old sequence number and use it (items have been skipped). if $LISPLIB and $compileOnlyCertainItems then parts := splitEncodedFunctionName(u.0, ";") -- Next line JHD/SMWATT 7/17/86 to deal with inner functions parts='inner => $savableItems:=[u.0,:$savableItems] unew := nil for [s,t] in $splitUpItemsAlreadyThere repeat if parts.0=s.0 and parts.1=s.1 and parts.2=s.2 then unew := t null unew => sayBrightly ['" Error: Item did not previously exist"] sayBrightly ['" Item not saved: ", :bright u.0] sayBrightly ['" What's there is: ", $lisplibItemsAlreadyThere] nil sayBrightly ['" Renaming ", u.0, '" as ", unew] u := [unew, :rest u] $savableItems := [unew, :$saveableItems] -- tested by embedded RWRITE optimizedBody:= optimizeFunctionDef u stuffToCompile:= if null $insideCapsuleFunctionIfTrue then optimizedBody else putInLocalDomainReferences optimizedBody $doNotCompileJustPrint=true => (PRETTYPRINT stuffToCompile; op') $macroIfTrue => constructMacro stuffToCompile -- Let the backend know about this function's type if $insideCapsuleFunctionIfTrue and $optProclaim then proclaimCapsuleFunction(op',$signatureOfForm) result:= spadCompileOrSetq stuffToCompile functionStats:=[0,elapsedTime()] $functionStats:= addStats($functionStats,functionStats) printStats functionStats result ++ Subroutine of compile. Called to generate backend code for ++ items defined directly or indirectly at capsule level. This is ++ also used to compile functors. spadCompileOrSetq (form is [nam,[lam,vl,body]]) == --bizarre hack to take account of the existence of "known" functions --good for performance (LISPLLIB size, BPI size, NILSEC) CONTAINED($ClearBodyToken,body) => sayBrightly ['" ",:bright nam,'" not compiled"] -- flag parameters needs to be made atomic, otherwise Lisp is confused. -- We try our best to preserve -- Note that we don't need substitution in the body because flag -- parameters are never used in the body. vl := [ renameParameter for v in vl] where renameParameter() == NUMBERP v or IDENTP v or string? v => v gensym '"flag" clearReplacement nam -- Make sure we have fresh info if $optReplaceSimpleFunctions then body := replaceSimpleFunctions body if nam' := forwardingCall?(vl,body) then registerFunctionReplacement(nam,nam') sayBrightly ['" ",:bright nam,'"is replaced by",:bright nam'] else if macform := expandableDefinition?(vl,body) then registerFunctionReplacement(nam,macform) sayBrightly ['" ",:bright nam,'"is replaced by",:bright body] form := getFunctionReplacement nam => [nam,[lam,vl,["DECLARE",["IGNORE",last vl]],body]] [nam,[lam,vl,body]] $insideCapsuleFunctionIfTrue => $optExportedFunctionReference => $capsuleFunctionStack := [form,:$capsuleFunctionStack] first form first backendCompile [form] compileConstructor form compileConstructor form == u:= compileConstructor1 form clearClams() --clear all CLAMmed functions u compileConstructor1 (form:=[fn,[key,vl,:bodyl]]) == -- fn is the name of some category/domain/package constructor; -- we will cache all of its values on $ConstructorCache with reference -- counts $clamList: local := nil lambdaOrSlam := getConstructorKindFromDB fn = "category" => 'SPADSLAM $mutableDomain => 'LAMBDA $clamList:= [[fn,"$ConstructorCache",'domainEqualList,'count],:$clamList] 'LAMBDA compForm:= [[fn,[lambdaOrSlam,vl,:bodyl]]] if getConstructorKindFromDB fn = "category" then u:= compAndDefine compForm else u:= backendCompile compForm clearConstructorCache fn --clear cache for constructor first u constructMacro: %Form -> %Form constructMacro (form is [nam,[lam,vl,body]]) == not (and/[atom x for x in vl]) => stackSemanticError(["illegal parameters for macro: ",vl],nil) ["XLAM",vl':= [x for x in vl | IDENTP x],body] listInitialSegment(u,v) == null u => true null v => nil first u=first v and listInitialSegment(rest u,rest v) --returns true iff u.i=v.i for i in 1..(#u)-1 modemap2Signature [[.,:sig],:.] == sig uncons: %Form -> %Form uncons x == atom x => x x is ["CONS",a,b] => [a,:uncons b] --% CAPSULE bootStrapError(functorForm,sourceFile) == ['COND, _ ['$bootStrapMode, _ ['VECTOR,mkTypeForm functorForm,nil,nil,nil,nil,nil]], [''T, ['systemError,['LIST,''%b,MKQ functorForm.op,''%d,'"from", _ ''%b,MKQ namestring sourceFile,''%d,'"needs to be compiled"]]]] registerInlinableDomain(x,e) == macroExpand(x,e) is [ctor,:.] and constructor? ctor => nominateForInlining ctor compAdd(['add,$addForm,capsule],m,e) == $bootStrapMode = true => if $addForm is ["%Comma",:.] then code := nil else [code,m,e]:= comp($addForm,m,e) [['COND, _ ['$bootStrapMode, _ code],_ [''T, ['systemError,['LIST,''%b,MKQ $functorForm.op,''%d,'"from", _ ''%b,MKQ namestring _/EDITFILE,''%d,'"needs to be compiled"]]]],m,e] $addFormLhs: local:= $addForm if $addForm is ["SubDomain",domainForm,predicate] then $NRTaddForm := domainForm NRTgetLocalIndex domainForm registerInlinableDomain(domainForm,e) --need to generate slot for add form since all $ go-get -- slots will need to access it [$addForm,.,e]:= compSubDomain1(domainForm,predicate,m,e) else $NRTaddForm := $addForm [$addForm,.,e]:= $addForm is ["%Comma",:.] => $NRTaddForm := ["%Comma",:[NRTgetLocalIndex x for x in $addForm.args]] for x in $addForm.args repeat registerInlinableDomain(x,e) compOrCroak(compTuple2Record $addForm,$EmptyMode,e) registerInlinableDomain($addForm,e) compOrCroak($addForm,$EmptyMode,e) compCapsule(capsule,m,e) compTuple2Record u == ['Record,:[[":",i,x] for i in 1.. for x in u.args]] compCapsule(['CAPSULE,:itemList],m,e) == $bootStrapMode = true => [bootStrapError($functorForm, _/EDITFILE),m,e] $insideExpressionIfTrue: local:= false $useRepresentationHack := true clearCapsuleFunctionTable() e := checkRepresentation($addFormLhs,itemList,e) compCapsuleInner(itemList,m,addDomain('_$,e)) compSubDomain(["SubDomain",domainForm,predicate],m,e) == $addFormLhs: local:= domainForm $addForm: local := nil $NRTaddForm := domainForm [$addForm,.,e]:= compSubDomain1(domainForm,predicate,m,e) compCapsule(['CAPSULE],m,e) compSubDomain1(domainForm,predicate,m,e) == [.,.,e]:= compMakeDeclaration("#1",domainForm,addDomain(domainForm,e)) u:= compCompilerPredicate(predicate,e) or stackSemanticError(["predicate: ",predicate, " cannot be interpreted with #1: ",domainForm],nil) pred := lispize u.expr -- For now, reject predicates that directly reference domains CONTAINED("$",pred) => stackAndThrow('"predicate %1pb is not simple enough",[predicate]) emitSubdomainInfo($form,domainForm,pred) $lisplibSuperDomain := [domainForm,predicate] [domainForm,m,e] compCapsuleInner(itemList,m,e) == e:= addInformation(m,e) --puts a new 'special' property of $Information data:= ["PROGN",:itemList] --RPLACd by compCapsuleItems and Friends e:= compCapsuleItems(itemList,nil,e) localParList:= $functorLocalParameters if $addForm then data:= ['add,$addForm,data] code:= $insideCategoryIfTrue and not $insideCategoryPackageIfTrue => data processFunctor($form,$signature,data,localParList,e) [MKPF([:$getDomainCode,code],"PROGN"),m,e] --% PROCESS FUNCTOR CODE processFunctor(form,signature,data,localParList,e) == form is ["CategoryDefaults"] => error "CategoryDefaults is a reserved name" buildFunctor(form,signature,data,localParList,e) compCapsuleItems(itemlist,$predl,$e) == $signatureOfForm: local := nil $suffix: local:= 0 for item in itemlist repeat $e:= compSingleCapsuleItem(item,$predl,$e) $e compSingleCapsuleItem(item,$predl,$e) == doIt(macroExpandInPlace(item,$e),$predl) $e ++ subroutine of doIt. Called to generate runtime noop insn. mutateToNothing item == item.op := 'PROGN item.rest := NIL doIt(item,$predl) == $GENNO: local:= 0 item is ['SEQ,:l,['exit,1,x]] => item.op := "PROGN" lastNode(item).first := x for it1 in rest item repeat $e:= compSingleCapsuleItem(it1,$predl,$e) --This will RPLAC as appropriate isDomainForm(item,$e) => -- convert naked top level domains to import. -- Note: The apparent useless destructing of `item' below is necessary -- because it is subject to RPLACA/RPLACD, which would create -- a cycle otherwise. u:= ["import", [first item,:rest item]] stackWarning('"Use: import %1p",[[first item,:rest item]]) item.op := u.op item.rest := rest u doIt(item,$predl) item is ["%LET",lhs,rhs,:.] => compOrCroak(item,$EmptyMode,$e) isnt [code,.,$e] => stackSemanticError(["cannot compile assigned value to",:bright lhs],nil) not (code is ["%LET",lhs',rhs',:.] and atom lhs') => code is ["PROGN",:.] => stackSemanticError(["multiple assignment ",item," not allowed"],nil) item.first := first code item.rest := rest code lhs:= lhs' if not member(KAR rhs,$NonMentionableDomainNames) and not MEMQ(lhs, $functorLocalParameters) then $functorLocalParameters:= [:$functorLocalParameters,lhs] if code is ["%LET",.,rhs',:.] and isDomainForm(rhs',$e) then if lhs="Rep" then --$Representation bound by compDefineFunctor, used in compNoStacking $Representation := getRepresentation $e if $optimizeRep then nominateForInlining $Representation code is ["%LET",:.] => item.op := "setShellEntry" rhsCode := rhs' item.rest := ['$,NRTgetLocalIndex lhs,rhsCode] item.op := code.op item.rest := rest code item is [":",a,t] => [.,.,$e]:= compOrCroak(item,$EmptyMode,$e) item is ["import",:doms] => for dom in doms repeat sayBrightly ['" importing ",:formatUnabbreviated dom] [.,.,$e] := compOrCroak(item,$EmptyMode,$e) mutateToNothing item item is ["%Inline",type] => processInlineRequest(type,$e) mutateToNothing item item is ["%SignatureImport",:.] => [.,.,$e] := compSignatureImport(item,$EmptyMode,$e) mutateToNothing item item is ["IF",p,x,y] => doItConditionally(item,$predl) item is ["where",b,:l] => compOrCroak(item,$EmptyMode,$e) item is ["MDEF",:.] => [.,.,$e]:= compOrCroak(item,$EmptyMode,$e) item is ['DEF,[op,:.],:.] => body := isMacro(item,$e) => $e := putMacro(op,body,$e) [.,.,$e]:= t:= compOrCroak(item,$EmptyMode,$e) item.op := "CodeDefine" --Note that DescendCode, in CodeDefine, is looking for this second(item).rest := [$signatureOfForm] --This is how the signature is updated for buildFunctor to recognise functionPart:= ['dispatchFunction,t.expr] item.rest.rest.first := functionPart item.rest.rest.rest := nil u:= compOrCroak(item,$EmptyMode,$e) => ([code,.,$e]:= u; item.first := first code; item.rest := rest code) systemErrorHere ["doIt", item] isMacro(x,e) == x is ['DEF,[op,:args],signature,specialCases,body] and null get(op,'modemap,e) and null args and null get(op,'mode,e) and signature is [nil] => body ++ Compile capsule-level `item' which is a conditional expression. ++ OpenAxiom's take on prepositional logical is a constructive ++ interpretation of logical connectives, in terms of IF-expresions. ++ In particular, a negation is positively interpretated by swapping ++ branches, and- and or-expressions are decomposed into nested ++ IF-expressions. -- gdr, 2009-06-15. doItConditionally(item,predl) == item isnt ["IF",p,x,y] => systemErrorHere ["doItConditionally",item] p is ["not",p'] => -- swap branches and recurse for positive interpretation. item.rest.first := p' item.rest.rest.first := y item.rest.rest.rest.first := x doItConditionally(item,predl) p is ["and",p',p''] => item.rest.first := p' item.rest.rest.first := ["IF",p'',x,COPY y] doItConditionally(item,predl) p is ["or",p',p''] => item.rest.first := p' item.rest.rest.rest.first := ["IF",p'',COPY x,y] doItConditionally(item,predl) doItIf(item,predl,$e) doItIf(item is [.,p,x,y],$predl,$e) == olde:= $e [p',.,$e]:= compCompilerPredicate(p,$e) or userError ['"not a Boolean:",p] oldFLP:=$functorLocalParameters if x~="%noBranch" then compSingleCapsuleItem(x,[p,:$predl],getSuccessEnvironment(p,$e)) x':=localExtras(oldFLP) oldFLP:=$functorLocalParameters if y~="%noBranch" then compSingleCapsuleItem(y,[["not",p],:$predl],getInverseEnvironment(p,olde)) y':=localExtras(oldFLP) item.op := "COND" item.rest := [[p',x,:x'],['(QUOTE T),y,:y']] where localExtras(oldFLP) == EQ(oldFLP,$functorLocalParameters) => NIL flp1:=$functorLocalParameters oldFLP':=oldFLP n:=0 while oldFLP' repeat oldFLP':=rest oldFLP' flp1:=rest flp1 n:=n+1 -- Now we have to add code to compile all the elements -- of functorLocalParameters that were added during the -- conditional compilation nils:=ans:=[] for u in flp1 repeat -- is =u form always an atom? if atom u or (or/[v is [.,=u,:.] for v in $getDomainCode]) then nils:=[u,:nils] else gv := gensym() ans:=[["%LET",gv,u],:ans] nils:=[gv,:nils] n:=n+1 $functorLocalParameters:=[:oldFLP,:nreverse nils] nreverse ans --% CATEGORY AND DOMAIN FUNCTIONS compContained: (%Form, %Mode, %Env) -> %Maybe %Triple compContained(["CONTAINED",a,b],m,e) == [a,ma,e]:= comp(a,$EmptyMode,e) or return nil [b,mb,e]:= comp(b,$EmptyMode,e) or return nil isCategoryForm(ma,e) and isCategoryForm(mb,e) => (T:= [["CONTAINED",a,b],$Boolean,e]; convert(T,m)) nil compJoin(["Join",:argl],m,e) == catList:= [(compForMode(x,$Category,e) or return 'failed).expr for x in argl] catList='failed => stackSemanticError(["cannot form Join of: ",argl],nil) catList':= [extract for x in catList] where extract() == isCategoryForm(x,e) => parameters:= union("append"/[getParms(y,e) for y in rest x],parameters) where getParms(y,e) == atom y => isDomainForm(y,e) => [y] nil y is ['LENGTH,y'] => [y,y'] [y] x x is ["DomainSubstitutionMacro",pl,body] => (parameters:= union(pl,parameters); body) x is ["mkCategory",:.] => x atom x and getmode(x,e)=$Category => x stackSemanticError(["invalid argument to Join: ",x],nil) x T:= [wrapDomainSub(parameters,["Join",:catList']),$Category,e] convert(T,m) compForMode: (%Form,%Mode,%Env) -> %Maybe %Triple compForMode(x,m,e) == $compForModeIfTrue: local:= true comp(x,m,e) makeCategoryForm(c,e) == not isCategoryForm(c,e) => nil [x,m,e]:= compOrCroak(c,$EmptyMode,e) [x,e] mustInstantiate: %Form -> %Thing mustInstantiate D == D is [fn,:.] and not (MEMQ(fn,$DummyFunctorNames) or GET(fn,"makeFunctionList")) wrapDomainSub: (%List, %Form) -> %Form wrapDomainSub(parameters,x) == ["DomainSubstitutionMacro",parameters,x] mkExplicitCategoryFunction(domainOrPackage,sigList,atList) == body:= ["mkCategory",MKQ domainOrPackage,['LIST,:reverse sigList], ['LIST,:reverse atList],MKQ domList,nil] where domList() == ("union"/[fn sig for ["QUOTE",[[.,sig,:.],:.]] in sigList]) where fn sig == [D for D in sig | mustInstantiate D] parameters:= removeDuplicates ("append"/ [[x for x in sig | IDENTP x and x~='_$] for ["QUOTE",[[.,sig,:.],:.]] in sigList]) wrapDomainSub(parameters,body) DomainSubstitutionFunction(parameters,body) == --see definition of DomainSubstitutionMacro in SPAD LISP if parameters then (body:= Subst(parameters,body)) where Subst(parameters,body) == atom body => MEMQ(body,parameters) => MKQ body body member(body,parameters) => g:=gensym() $extraParms:=PUSH([g,:body],$extraParms) --Used in SetVector12 to generate a substitution list --bound in buildFunctor --For categories, bound and used in compDefineCategory MKQ g body.op = "QUOTE" => body cons? $definition and isFunctor body.op and body.op ~= $definition.op => ['QUOTE,optimize body] [Subst(parameters,u) for u in body] not (body is ["Join",:.]) => body atom $definition => body null $definition.args => body --should not bother if it will only be called once name:= INTERN strconc(KAR $definition,";CAT") SETANDFILE(name,nil) body:= ["COND",[name],['(QUOTE T),['SETQ,name,body]]] body ++ Subroutine of compCategoryItem. ++ Compile exported signature `opsig' under predicate `pred' in ++ environment `env'. compSignature(opsig,pred,env) == [op,:sig] := opsig not atom op => for y in op repeat compSignature([y,:sig],pred,env) op in '(per rep) => stackSemanticError(['"cannot export signature for", :bright op],nil) nil noteExport(opsig,pred) PUSH(MKQ [opsig,pred],$sigList) compCategoryItem(x,predl,env) == x is nil => nil --1. if x is a conditional expression, recurse; otherwise, form the predicate x is ["COND",[p,e]] => predl':= [p,:predl] e is ["PROGN",:l] => for y in l repeat compCategoryItem(y,predl',env) compCategoryItem(e,predl',env) x is ["IF",a,b,c] => a is ["not",p] => compCategoryItem(["IF",p,c,b],predl,env) a is ["and",p,q] => compCategoryItem(["IF",p,["IF",q,b,c],COPY c],predl,env) a is ["or",p,q] => compCategoryItem(["IF",p,b,["IF",q,COPY b,c]],predl,env) predl':= [a,:predl] if b~="%noBranch" then b is ["PROGN",:l] => for y in l repeat compCategoryItem(y,predl',env) compCategoryItem(b,predl',env) c="%noBranch" => nil predl':= [["not",a],:predl] c is ["PROGN",:l] => for y in l repeat compCategoryItem(y,predl',env) compCategoryItem(c,predl',env) pred := (predl => MKPF(predl,"AND"); true) --2. if attribute, push it and return x is ["ATTRIBUTE",y] => -- Attribute 'nil' carries no semantics. y = "nil" => nil noteExport(y,pred) PUSH(MKQ [y,pred],$atList) --3. it may be a list, with PROGN as the first, and some information as the rest x is ["PROGN",:l] => for u in l repeat compCategoryItem(u,predl,env) -- 4. otherwise, x gives a signature for a -- single operator name or a list of names; if a list of names, -- recurse x is ["SIGNATURE",:opsig] => compSignature(opsig,pred,env) systemErrorHere ["compCategoryItem",x] compCategory: (%Form,%Mode,%Env) -> %Maybe %Triple compCategory(x,m,e) == clearExportsTable() (m:= resolve(m,$Category))=$Category and x is ['CATEGORY, domainOrPackage,:l] => $sigList: local := nil $atList: local := nil for x in l repeat compCategoryItem(x,nil,e) rep:= mkExplicitCategoryFunction(domainOrPackage,$sigList,$atList) --if inside compDefineCategory, provide for category argument substitution [rep,m,e] systemErrorHere ["compCategory",x] --%