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|
-- Copyright (c) 1991-2002, The Numerical Algorithms Group Ltd.
-- All rights reserved.
-- Copyright (C) 2007-2009, 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 g_-util
import g_-opt
namespace BOOT
module c_-util where
clearReplacement: %Symbol -> %Thing
replaceSimpleFunctions: %Form -> %Form
foldExportedFunctionReferences: %List -> %List
diagnoseUknownType: (%Mode,%Env) -> %Form
--%
++ if true continue compiling after errors
$scanIfTrue := false
+++ If non nil, holds compiled value of 'Rep' of the current domain.
$Representation := nil
$formalArgList := []
++ The formal body of the category being currently compiled.
$currentCategoryBody := nil
$compErrorMessageStack := nil
--% Optimization control
++ true if we have to proclaim function signatures in the generated Lisp.
$optProclaim := false
++ true if we have to inline simple functions before codegen.
$optReplaceSimpleFunctions := false
++ true if we have to resolve references to exported operations.
$optExportedFunctionReference := false
--%
++ If using old `Rep' definition semantics, return `$' when m is `Rep'.
++ Otherwise, return `m'.
dollarIfRepHack m ==
m = "Rep" and $useRepresentationHack => "$"
m
++ The inverse of the above.
RepIfRepHack m ==
m = "$" and $useRepresentationHack => "Rep"
m
++ If using old `Rep' definition semantics, return `$' is m is `Rep'.
-- ??? Eventually this and the above should be merged and/or removed.
substituteDollarIfRepHack m ==
$useRepresentationHack => substitute("$","Rep",m)
m
++ Return the triple for the representation domain for the
++ current functor, if any.
getRepresentation: %Env -> %Maybe %Mode
getRepresentation e ==
(get("Rep","value",e) or return nil).expr
++ Returns true if the form `t' is an instance of the Tuple constructor.
isTupleInstance: %Form -> %Boolean
isTupleInstance t ==
t is ["Tuple",.]
++ Returns true if the signature `sig' describes a function that can
++ accept a homogeneous variable length argument list.
isHomoegenousVarargSignature: %Signature -> %Boolean
isHomoegenousVarargSignature sig ==
#sig = 1 and isTupleInstance first sig
++ Returns true if the arguments list `args' match in shape the
++ parameter type list `sig'. This means that either the number
++ of arguments is exactly the number of parameters, or that the
++ signature describes a homogeneous vararg operation.
enoughArguments: (%List,%Signature) -> %Boolean
enoughArguments(args,sig) ==
#args = #sig or isHomoegenousVarargSignature sig
++ Returns true if the operation described by the signature `sig'
++ wants its arguments as a Tuple object.
wantArgumentsAsTuple: (%List,%Signature) -> %Boolean
wantArgumentsAsTuple(args,sig) ==
isHomoegenousVarargSignature sig and #args ^= #sig
devaluate d ==
not REFVECP d => d
QSGREATERP(QVSIZE d,5) and getShellEntry(d,3) is ['Category] =>
getShellEntry(d,0)
QSGREATERP(QVSIZE d,0) =>
d':=getShellEntry(d,0)
isFunctor d' => d'
d
d
devaluateList l == [devaluate d for d in l]
devaluateDeeply x ==
VECP x => devaluate x
atom x => x
[devaluateDeeply y for y in x]
--% Debugging Functions
--CONTINUE() == continue()
continue() == FIN comp($x,$m,$f)
LEVEL(:l) == APPLY('level,l)
level(:l) ==
null l => same()
l is [n] and INTEGERP n => displayComp ($level:= n)
SAY '"Correct format: (level n) where n is the level you want to go to"
UP() == up()
up() == displayComp ($level:= $level-1)
SAME() == same()
same() == displayComp $level
DOWN() == down()
down() == displayComp ($level:= $level+1)
displaySemanticErrors() ==
n:= #($semanticErrorStack:= REMDUP $semanticErrorStack)
n=0 => nil
l:= NREVERSE $semanticErrorStack
$semanticErrorStack:= nil
sayBrightly bright '" Semantic Errors:"
displaySemanticError(l,$OutputStream)
sayBrightly '" "
displayWarnings()
displaySemanticError(l,stream) ==
for x in l for i in 1.. repeat
sayBrightly(['" [",i,'"] ",:first x],stream)
displayWarnings() ==
n:= #($warningStack:= REMDUP $warningStack)
n=0 => nil
sayBrightly bright '" Warnings:"
l := NREVERSE $warningStack
displayWarning(l,$OutputStream)
$warningStack:= nil
sayBrightly '" "
displayWarning(l,stream) ==
for x in l for i in 1.. repeat
sayBrightly(['" [",i,'"] ",:x],stream)
displayComp level ==
$bright:= " << "
$dim:= " >> "
if $insideCapsuleFunctionIfTrue=true then
sayBrightly ['"error in function",:bright $op,'%l]
--mathprint removeZeroOne mkErrorExpr level
pp removeZeroOne mkErrorExpr level
sayBrightly ['"****** level",:bright level,'" ******"]
[$x,$m,$f,$exitModeStack]:= ELEM($s,level)
SAY("$x:= ",$x)
SAY("$m:= ",$m)
SAY "$f:="
F_,PRINT_-ONE $f
nil
mkErrorExpr level ==
bracket ASSOCLEFT DROP(level-#$s,$s) where
bracket l ==
#l<2 => l
l is [a,b] =>
highlight(b,a) where
highlight(b,a) ==
atom b =>
substitute(var,b,a) where
var:= INTERN STRCONC(STRINGIMAGE $bright,STRINGIMAGE b,STRINGIMAGE $dim)
highlight1(b,a) where
highlight1(b,a) ==
atom a => a
a is [ =b,:c] => [$bright,b,$dim,:c]
[highlight1(b,first a),:highlight1(b,rest a)]
substitute(bracket rest l,first rest l,first l)
compAndTrace [x,m,e] ==
SAY("tracing comp, compFormWithModemap of: ",x)
TRACE_,1(["comp","compFormWithModemap"],nil)
T:= comp(x,m,e)
UNTRACE_,1 "comp"
UNTRACE_,1 "compFormWithModemap"
T
errorRef s ==
stackWarning('"%1b has no value", [s])
unErrorRef s ==
unStackWarning('"'%1b has no value",[s])
--% ENVIRONMENT FUNCTIONS
consProplistOf(var,proplist,prop,val) ==
semchkProplist(var,proplist,prop,val)
$InteractiveMode and (u:= assoc(prop,proplist)) =>
RPLACD(u,val)
proplist
[[prop,:val],:proplist]
warnLiteral x ==
stackWarning('"%1b is BOTH a variable a literal",[x])
intersectionEnvironment(e,e') ==
ce:= makeCommonEnvironment(e,e')
ic:= intersectionContour(deltaContour(e,ce),deltaContour(e',ce))
e'':= (ic => addContour(ic,ce); ce)
--$ie:= e'' this line is for debugging purposes only
deltaContour([[c,:cl],:el],[[c',:cl'],:el']) ==
^el=el' => systemError '"deltaContour" --a cop out for now
eliminateDuplicatePropertyLists contourDifference(c,c') where
contourDifference(c,c') == [first x for x in tails c while (x^=c')]
eliminateDuplicatePropertyLists contour ==
contour is [[x,:.],:contour'] =>
LASSOC(x,contour') =>
--save some CONSing if possible
[first contour,:DELLASOS(x,eliminateDuplicatePropertyLists contour')]
[first contour,:eliminateDuplicatePropertyLists contour']
nil
intersectionContour(c,c') ==
$var: local
computeIntersection(c,c') where
computeIntersection(c,c') ==
varlist:= REMDUP ASSOCLEFT c
varlist':= REMDUP ASSOCLEFT c'
interVars:= intersection(varlist,varlist')
unionVars:= union(varlist,varlist')
diffVars:= setDifference(unionVars,interVars)
modeAssoc:= buildModeAssoc(diffVars,c,c')
[:modeAssoc,:
[[x,:proplist]
for [x,:y] in c | member(x,interVars) and
(proplist:= interProplist(y,LASSOC($var:= x,c')))]]
interProplist(p,p') ==
--p is new proplist; p' is old one
[:modeCompare(p,p'),:[pair' for pair in p | (pair':= compare(pair,p'))]]
buildModeAssoc(varlist,c,c') ==
[[x,:mp] for x in varlist | (mp:= modeCompare(LASSOC(x,c),LASSOC(x,c')))]
compare(pair is [prop,:val],p') ==
--1. if the property-value pair are identical, accept it immediately
pair=(pair':= assoc(prop,p')) => pair
--2. if property="value" and modes are unifiable, give intersection
-- property="value" but value=genSomeVariable)()
(val':= KDR pair') and prop="value" and
(m:= unifiable(val.mode,val'.mode)) => ["value",genSomeVariable(),m,nil]
--this tells us that an undeclared variable received
--two different values but with identical modes
--3. property="mode" is covered by modeCompare
prop="mode" => nil
modeCompare(p,p') ==
pair:= assoc("mode",p) =>
pair':= assoc("mode",p') =>
m'':= unifiable(rest pair,rest pair') => LIST ["mode",:m'']
stackSemanticError(['%b,$var,'%d,"has two modes: "],nil)
--stackWarning ("mode for",'%b,$var,'%d,"introduced conditionally")
LIST ["conditionalmode",:rest pair]
--LIST pair
--stackWarning ("mode for",'%b,$var,'%d,"introduced conditionally")
pair':= assoc("mode",p') => LIST ["conditionalmode",:rest pair']
--LIST pair'
unifiable(m1,m2) ==
m1=m2 => m1
--we may need to add code to coerce up to tagged unions
--but this can not be done here, but should be done by compIf
m:=
m1 is ["Union",:.] =>
m2 is ["Union",:.] => ["Union",:S_+(rest m1,rest m2)]
["Union",:S_+(rest m1,[m2])]
m2 is ["Union",:.] => ["Union",:S_+(rest m2,[m1])]
["Union",m1,m2]
for u in getDomainsInScope $e repeat
if u is ["Union",:u'] and (and/[member(v,u') for v in rest m]) then
return m
--this loop will return NIL if not satisfied
addContour(c,E is [cur,:tail]) ==
[NCONC(fn(c,E),cur),:tail] where
fn(c,e) ==
for [x,:proplist] in c repeat
fn1(x,proplist,getProplist(x,e)) where
fn1(x,p,ee) ==
for pv in p repeat fn3(x,pv,ee) where
fn3(x,pv,e) ==
[p,:v]:=pv
if member(x,$getPutTrace) then
pp([x,"has",pv])
if p="conditionalmode" then
RPLACA(pv,"mode")
--check for conflicts with earlier mode
if vv:=LASSOC("mode",e) then
if v ^=vv then
stackWarning('"The conditional modes %1p and %2p conflict",
[v,vv])
LIST c
makeCommonEnvironment(e,e') ==
interE makeSameLength(e,e') where --$ie:=
interE [e,e'] ==
rest e=rest e' => [interLocalE makeSameLength(first e,first e'),:rest e]
interE [rest e,rest e']
interLocalE [le,le'] ==
rest le=rest le' =>
[interC makeSameLength(first le,first le'),:rest le]
interLocalE [rest le,rest le']
interC [c,c'] ==
c=c' => c
interC [rest c,rest c']
makeSameLength(x,y) ==
fn(x,y,#x,#y) where
fn(x,y,nx,ny) ==
nx>ny => fn(rest x,y,nx-1,ny)
nx<ny => fn(x,rest y,nx,ny-1)
[x,y]
printEnv E ==
for x in E for i in 1.. repeat
for y in x for j in 1.. repeat
SAY('"******CONTOUR ",j,'", LEVEL ",i,'":******")
for z in y repeat
TERPRI()
SAY("Properties Of: ",first z)
for u in rest z repeat
PRIN1 first u
printString ": "
PRETTYPRINT tran(rest u,first u) where
tran(val,prop) ==
prop="value" => DROP(-1,val)
val
prEnv E ==
for x in E for i in 1.. repeat
for y in x for j in 1.. repeat
SAY('"******CONTOUR ",j,'", LEVEL ",i,'":******")
for z in y | not LASSOC("modemap",rest z) repeat
TERPRI()
SAY("Properties Of: ",first z)
for u in rest z repeat
PRIN1 first u
printString ": "
PRETTYPRINT tran(rest u,first u) where
tran(val,prop) ==
prop="value" => DROP(-1,val)
val
prModemaps E ==
listOfOperatorsSeenSoFar:= nil
for x in E for i in 1.. repeat
for y in x for j in 1.. repeat
for z in y | null member(first z,listOfOperatorsSeenSoFar) and
(modemap:= LASSOC("modemap",rest z)) repeat
listOfOperatorsSeenSoFar:= [first z,:listOfOperatorsSeenSoFar]
TERPRI()
PRIN1 first z
printString ": "
PRETTYPRINT modemap
prTriple T ==
SAY '"Code:"
pp T.0
SAY '"Mode:"
pp T.1
TrimCF() ==
new:= nil
old:= CAAR $CategoryFrame
for u in old repeat
if not ASSQ(first u,new) then
uold:= rest u
unew:= nil
for v in uold repeat if not ASSQ(first v,unew) then unew:= [v,:unew]
new:= [[first u,:NREVERSE unew],:new]
$CategoryFrame:= [[NREVERSE new]]
nil
--%
isKnownCategory: (%Mode,%Env) -> %Boolean
isKnownCategory(c,e) ==
c = $Type => true
c = $Category => true
[ctor,:args] := c
ctor = "Join" => true -- don't check arguments yet.
ctor = "SubsetCategory" => true -- ditto
get(ctor,"isCategory",e) => true
false
--TRACE isKnownCategory
++ Returns non-nil if `t' is a known type in the environement `e'.
diagnoseUknownType(t,e) ==
atom t =>
t in '($ constant) => t
t' := assoc(t,getDomainsInScope e) => t'
(m := getmode(t,e)) and isKnownCategory(m,$CategoryFrame) => t
STRINGP t => t
-- ??? We should not to check for $$ at this stage.
-- ??? This is a bug in the compiler that needs to be fixed.
t = "$$" => t
stackSemanticError(['"The identifier", :bright t,
'"is not known to name a type"],nil)
[ctor,:args] := t
ctor = "Mapping" =>
for t' in args repeat diagnoseUknownType(t',e)
t
ctor = "Record" =>
for [.,.,t'] in args repeat diagnoseUknownType(t',e)
t
ctor = "Union" =>
if args is [[":",:.],:.] then
for [.,.,t'] in args repeat diagnoseUknownType(t',e)
else
for t' in args repeat diagnoseUknownType(t',e)
t
ctor = "Enumeration" =>
for t' in args repeat
IDENTP t' => nil
stackSemanticError(['"Enumerators must be symbols."], nil)
t
ctor = "[||]" => t
ctor in $BuiltinConstructorNames => t -- ??? check Record and Union fields
-- ??? Ideally `e' should be a local extension of $CategoryFrame
-- ??? so that we don't have to access it here as a global state.
get(ctor,"isFunctor",$CategoryFrame)
or get(ctor,"isCategory",$CategoryFrame) => t
-- ctor maybe a constructor, but user forgot to import. Warn.
getConstructorAbbreviationFromDB ctor =>
stackWarning('"Type %1pb is not in scope. Import it",[t])
t
stackSemanticError(['"Identifier", :bright ctor,
'"is not known to name a constructor"],nil)
--% PREDICATES
isConstantId(name,e) ==
IDENTP name =>
pl:= getProplist(name,e) =>
(LASSOC("value",pl) or LASSOC("mode",pl) => false; true)
true
false
isFalse() == nil
isFluid s == atom s and "$"=(PNAME s).(0)
isFunction(x,e) ==
get(x,"modemap",e) or GETL(x,"SPECIAL") or x="case" or getmode(x,e) is [
"Mapping",:.]
isLiteral: (%Symbol,%Env) -> %Boolean
isLiteral(x,e) ==
get(x,"isLiteral",e) => true
false
makeLiteral: (%Symbol,%Env) -> %Thing
makeLiteral(x,e) ==
put(x,"isLiteral","true",e)
isSomeDomainVariable s ==
IDENTP s and #(x:= PNAME s)>2 and x.(0)="#" and x.(1)="#"
++ Return non-nil is the domain form `x' is a `subset' of domain
++ form `y' in the environment `e'. The relation of subdomain
++ is understood as equivalent to the fact that all values of
++ the domain designated by `x' are also values of the domain
++ designated by `y'. Examples include declaration of domain `x'
++ as satisfying SubsetCategory(SomeCategory, y). Or, when
++ x is defined as SubDomain(y,pred). In that case, the predicate
++ is returned and its parameter is `#1'.
isSubset(x,y,e) ==
x = y => true
-- Every domain or catgory is a subset of Type.
y = $Type => true
-- When using the old style definition, the current domain
-- is considered a subset of its representation domain
x = "$" and y = "Rep" => $useRepresentationHack
-- Or, if x has the Subsets property set by SubsetCategory.
pred := LASSOC(opOf x,get(opOf y,"Subsets",e)) => pred
-- Or, they are related by subdomain chain.
isDomainForm(x,e) and isSubDomain(x,y)
isDomainInScope(domain,e) ==
domainList:= getDomainsInScope e
atom domain =>
MEMQ(domain,domainList) => true
not IDENTP domain or isSomeDomainVariable domain => true
false
(name:= first domain)="Category" => true
ASSQ(name,domainList) => true
-- null CDR domain or domainMember(domain,domainList) => true
-- false
isFunctor name => false
true --is not a functor
isSymbol x == IDENTP x or x=nil
isSimple x ==
atom x or $InteractiveMode => true
x is [op,:argl] and
isSideEffectFree op and (and/[isSimple y for y in argl])
isSideEffectFree op ==
member(op,$SideEffectFreeFunctionList) or op is ["elt",.,op'] and
isSideEffectFree op'
isAlmostSimple x ==
--returns (<new predicate> . <list of assignments>) or nil
$assignmentList: local --$assigmentList is only used in this function
transform:=
fn x where
fn x ==
atom x or null rest x => x
[op,y,:l]:= x
op="has" => x
op="is" => x
op="%LET" =>
IDENTP y => (setAssignment LIST x; y)
(setAssignment [["%LET",g:= genVariable(),:l],["%LET",y,g]]; g)
op = "case" and IDENTP y => x
isSideEffectFree op => [op,:mapInto(rest x, function fn)]
$assignmentList:= "failed"
setAssignment x ==
$assignmentList="failed" => nil
$assignmentList:= [:$assignmentList,:x]
$assignmentList="failed" => nil
wrapSEQExit [:$assignmentList,transform]
incExitLevel u ==
adjExitLevel(u,1,1)
u
decExitLevel u ==
(adjExitLevel(u,1,-1); removeExit0 u) where
removeExit0 x ==
atom x => x
x is ["exit",0,u] => removeExit0 u
[removeExit0 first x,:removeExit0 rest x]
adjExitLevel(x,seqnum,inc) ==
atom x => x
x is [op,:l] and MEMQ(op,'(SEQ REPEAT COLLECT)) =>
for u in l repeat adjExitLevel(u,seqnum+1,inc)
x is ["exit",n,u] =>
(adjExitLevel(u,seqnum,inc); seqnum>n => x; rplac(CADR x,n+inc))
x is [op,:l] => for u in l repeat adjExitLevel(u,seqnum,inc)
wrapSEQExit l ==
null rest l => first l
[:c,x]:= [incExitLevel u for u in l]
["SEQ",:c,["exit",1,x]]
--% UTILITY FUNCTIONS
--appendOver x == "append"/x
removeEnv t == [t.expr,t.mode,$EmptyEnvironment] -- t is a triple
-- This function seems no longer used
--ordinsert(x,l) ==
-- null l => [x]
-- x=first l => l
-- _?ORDER(x,first l) => [x,:l]
-- [first l,:ordinsert(x,rest l)]
makeNonAtomic x ==
atom x => [x]
x
flatten(l,key) ==
null l => nil
first l is [k,:r] and k=key => [:r,:flatten(rest l,key)]
[first l,:flatten(rest l,key)]
genDomainVar() ==
$Index:= $Index+1
INTERNL STRCONC("#D",STRINGIMAGE $Index)
genVariable() ==
INTERNL STRCONC("#G",STRINGIMAGE ($genSDVar:= $genSDVar+1))
genSomeVariable() ==
INTERNL STRCONC("##",STRINGIMAGE ($genSDVar:= $genSDVar+1))
listOfIdentifiersIn x ==
IDENTP x => [x]
x is [op,:l] => REMDUP ("append"/[listOfIdentifiersIn y for y in l])
nil
mapInto(x,fn) == [FUNCALL(fn,y) for y in x]
numOfOccurencesOf(x,y) ==
fn(x,y,0) where
fn(x,y,n) ==
null y => 0
x=y => n+1
atom y => n
fn(x,first y,n)+fn(x,rest y,n)
compilerMessage(msg,args) ==
$PrintCompilerMessageIfTrue => sayPatternMsg(msg,args)
printDashedLine() ==
SAY
'"--------------------------------------------------------------------------"
stackSemanticError(msg,expr) ==
BUMPERRORCOUNT "semantic"
if $insideCapsuleFunctionIfTrue then msg:= [$op,": ",:msg]
if atom msg then msg:= LIST msg
entry:= [msg,expr]
if not member(entry,$semanticErrorStack) then $semanticErrorStack:=
[entry,:$semanticErrorStack]
$scanIfTrue and $insideCapsuleFunctionIfTrue=true and #$semanticErrorStack-
$initCapsuleErrorCount>3 => THROW("compCapsuleBody",nil)
nil
stackWarning(msg,args == nil) ==
msg := buildMessage(msg, args)
if $insideCapsuleFunctionIfTrue then msg:= [$op,": ",:msg]
if not member(msg,$warningStack) then $warningStack:= [msg,:$warningStack]
nil
unStackWarning(msg,args) ==
msg := buildMessage(msg,args)
if $insideCapsuleFunctionIfTrue then msg:= [$op,": ",:msg]
$warningStack:= EFFACE(msg,$warningStack)
nil
stackMessage(msg,args == nil) ==
if args ^= nil then
msg := buildMessage(msg,args)
$compErrorMessageStack:= [msg,:$compErrorMessageStack]
nil
stackMessageIfNone msg ==
--used in situations such as compForm where the earliest message is wanted
if null $compErrorMessageStack then $compErrorMessageStack:=
[msg,:$compErrorMessageStack]
nil
stackAndThrow(msg, args == nil) ==
if args ^= nil then
msg := buildMessage(msg,args)
$compErrorMessageStack:= [msg,:$compErrorMessageStack]
THROW("compOrCroak",nil)
printString x == PRINTEXP (STRINGP x => x; PNAME x)
printAny x == if atom x then printString x else PRIN1 x
printSignature(before,op,[target,:argSigList]) ==
printString before
printString op
printString ": _("
if argSigList then
printAny first argSigList
for m in rest argSigList repeat (printString ","; printAny m)
printString "_) -> "
printAny target
TERPRI()
elapsedTime() ==
currentTime:= TEMPUS_-FUGIT()
elapsedSeconds:= (currentTime-$previousTime)*QUOTIENT(1.0,$timerTicksPerSecond)
$previousTime:= currentTime
elapsedSeconds
addStats([a,b],[c,d]) == [a+c,b+d]
printStats [byteCount,elapsedSeconds] ==
timeString := normalizeStatAndStringify elapsedSeconds
if byteCount = 0 then SAY('"Time: ",timeString,'" SEC.") else
SAY('"Size: ",byteCount,'" BYTES Time: ",timeString,'" SEC.")
TERPRI()
nil
extendsCategoryForm(domain,form,form') ==
--is domain of category form also of category form'?
--domain is only used for SubsetCategory resolution.
--and ensuring that X being a Ring means that it
--satisfies (Algebra X)
form=form' => true
form=$Category => nil
form' is ["Join",:l] => and/[extendsCategoryForm(domain,form,x) for x in l]
form' is ["CATEGORY",.,:l] =>
and/[extendsCategoryForm(domain,form,x) for x in l]
form' is ["SubsetCategory",cat,dom] =>
extendsCategoryForm(domain,form,cat) and isSubset(domain,dom,$e)
form is ["Join",:l] => or/[extendsCategoryForm(domain,x,form') for x in l]
form is ["CATEGORY",.,:l] =>
member(form',l) or
stackWarning('"not known that %1 is of mode %2p",[form',form]) or true
-- if we are compiling the category `form', then we should look at
-- the body as provided in the current definition, not a version
-- possibly compiled previously that may have changed.
-- FIXME: should not we go all the way down and implement
-- polynormic recursion?
domain = "$" and form = $definition =>
extendsCategoryForm(domain, $currentCategoryBody, form')
isCategoryForm(form,$EmptyEnvironment) =>
--Constructs the associated vector
formVec:=(compMakeCategoryObject(form,$e)).expr
--Must be $e to pick up locally bound domains
form' is ["SIGNATURE",op,args,:.] =>
assoc([op,args],formVec.(1)) or
assoc(SUBSTQ(domain,"$",[op,args]),
SUBSTQ(domain,"$",formVec.(1)))
form' is ["ATTRIBUTE",at] =>
assoc(at,formVec.2) or
assoc(SUBSTQ(domain,"$",at),SUBSTQ(domain,"$",formVec.2))
form' is ["IF",:.] => true --temporary hack so comp won't fail
-- Are we dealing with an Aldor category? If so use the "has" function ...
# formVec = 1 => newHasTest(form,form')
catvlist:= formVec.4
member(form',first catvlist) or
member(form',SUBSTQ(domain,"$",first catvlist)) or
(or/
[extendsCategoryForm(domain,SUBSTQ(domain,"$",cat),form')
for [cat,:.] in CADR catvlist])
nil
getmode(x,e) ==
prop:=getProplist(x,e)
u:= LASSQ("value",prop) => u.mode
LASSQ("mode",prop)
getmodeOrMapping(x,e) ==
u:= getmode(x,e) => u
(u:= get(x,"modemap",e)) is [[[.,:map],.],:.] => ["Mapping",:map]
nil
outerProduct l ==
--of a list of lists
null l => LIST nil
"append"/[[[x,:y] for y in outerProduct rest l] for x in first l]
sublisR(al,u) ==
atom u => u
y:= rassoc(t:= [sublisR(al,x) for x in u],al) => y
true => t
substituteOp(op',op,x) ==
atom x => x
[(op=(f:= first x) => op'; f),:[substituteOp(op',op,y) for y in rest x]]
--substituteForFormalArguments(argl,expr) ==
-- SUBLIS([[v,:a] for a in argl for v in $FormalMapVariableList],expr)
-- following is only intended for substituting in domains slots 1 and 4
-- signatures and categories
sublisV(p,e) ==
(atom p => e; suba(p,e)) where
suba(p,e) ==
STRINGP e => e
-- no need to descend vectors unless they are categories
--REFVECP e => LIST2REFVEC [suba(p,e.i) for i in 0..MAXINDEX e]
isCategory e => LIST2REFVEC [suba(p,e.i) for i in 0..MAXINDEX e]
atom e => (y:= ASSQ(e,p) => rest y; e)
u:= suba(p,QCAR e)
v:= suba(p,QCDR e)
EQ(QCAR e,u) and EQ(QCDR e,v) => e
[u,:v]
--% DEBUGGING PRINT ROUTINES used in breaks
_?MODEMAPS x == _?modemaps x
_?modemaps x ==
env:=
$insideCapsuleFunctionIfTrue=true => $CapsuleModemapFrame
$f
x="all" => displayModemaps env
-- displayOpModemaps(x,old2NewModemaps get(x,"modemap",env))
displayOpModemaps(x,get(x,"modemap",env))
old2NewModemaps x ==
-- [[dcSig,pred] for [dcSig,[pred,:.],:.] in x]
x is [dcSig,[pred,:.],:.] => [dcSig,pred]
x
traceUp() ==
atom $x => sayBrightly "$x is an atom"
for y in rest $x repeat
u:= comp(y,$EmptyMode,$f) =>
sayBrightly [y,'" ==> mode",'%b,u.mode,'%d]
sayBrightly [y,'" does not compile"]
_?M x == _?m x
_?m x ==
u:= comp(x,$EmptyMode,$f) => u.mode
nil
traceDown() ==
mmList:= getFormModemaps($x,$f) =>
for mm in mmList repeat if u:= qModemap mm then return u
sayBrightly "no modemaps for $x"
qModemap mm ==
sayBrightly ['%b,"modemap",'%d,:formatModemap mm]
[[dc,target,:sl],[pred,:.]]:= mm
and/[qArg(a,m) for a in rest $x for m in sl] => target
sayBrightly ['%b,"fails",'%d,'%l]
qArg(a,m) ==
yesOrNo:=
u:= comp(a,m,$f) => "yes"
"no"
sayBrightly [a," --> ",m,'%b,yesOrNo,'%d]
yesOrNo="yes"
_?COMP x == _?comp x
_?comp x ==
msg:=
u:= comp(x,$EmptyMode,$f) =>
[MAKESTRING "compiles to mode",'%b,u.mode,'%d]
nil
sayBrightly msg
_?domains() == pp getDomainsInScope $f
_?DOMAINS() == ?domains()
_?mode x == displayProplist(x,[["mode",:getmode(x,$f)]])
_?MODE x == _?mode x
_?properties x == displayProplist(x,getProplist(x,$f))
_?PROPERTIES x == _?properties x
_?value x == displayProplist(x,[["value",:get(x,"value",$f)]])
_?VALUE x == _?value x
displayProplist(x,alist) ==
sayBrightly ["properties of",'%b,x,'%d,":"]
fn alist where
fn alist ==
alist is [[prop,:val],:l] =>
if prop="value" then val:= [val.expr,val.mode,'"..."]
sayBrightly [" ",'%b,prop,'%d,": ",val]
fn deleteAssoc(prop,l)
displayModemaps E ==
listOfOperatorsSeenSoFar:= nil
for x in E for i in 1.. repeat
for y in x for j in 1.. repeat
for z in y | null member(first z,listOfOperatorsSeenSoFar) and
(modemaps:= LASSOC("modemap",rest z)) repeat
listOfOperatorsSeenSoFar:= [first z,:listOfOperatorsSeenSoFar]
displayOpModemaps(first z,modemaps)
--% General object traversal functions
GCOPY ob == COPY ob -- for now
--%
++ format the set of candidate operations.
displayAmbiguousSignatures(op,sigs) ==
[:showCandidate(op, sig) for sig in sigs] where
showCandidate(op,sig) ==
["%l", " ", op, '": ",
:bright formatUnabbreviated ["Mapping",:sig]]
++ Display diagnostic message about ambiguous operation `op', with
++ possible resolutions given by the list `sigs'.
ambiguousSignatureError(op, sigs) ==
stackSemanticError(['"signature of lhs not unique. Candidates are:",
:displayAmbiguousSignatures($op,sigs)],nil)
--% Capsule Directory Management
++ Holds the list of slot number-export function pairs of
++ the current functor.
$capsuleDirectory := nil
clearCapsuleDirectory() ==
$capsuleDirectory := nil
$capsuleFunctionStack := nil
++ Return the linkage name of the exported operation associated with
++ slot number `slot'. A nil entry means that either the operation
++ is not defined, or it is conditional.
getCapsuleDirectoryEntry slot ==
rest ASSOC(slot,$capsuleDirectory)
++ Update the current capsule directory with entry controlled by
++ predicate `pred'.
updateCapsuleDirectory(item,pred) ==
pred ^= true => nil
entry :=
item is ["$",slot,["CONS",["dispatchFunction",fun],:.],:.] => [slot,:fun]
item is ["$",slot,["CONS","IDENTITY",
["FUNCALL",["dispatchFunction",fun],"$"]]] => [slot,:fun]
nil
entry = nil => nil
$capsuleDirectory := [entry,:$capsuleDirectory]
--% Tree walkers
++ Walk VM COND-form mutating sub-forms with unary
++ function `fun'
mutateCONDFormWithUnaryFunction(form,fun) ==
form isnt ["COND",:body] => form
for clauses in tails body repeat
-- a clause is a list of forms
for subForms in tails first clauses repeat
rplac(first subForms, FUNCALL(fun, first subForms))
form
++ Walk VM LET-form mutating enclosed expression forms with
++ unary function `fun'. Every sub-form is visited except
++ local variable declarations, though their initializers
++ are visited.
mutateLETFormWithUnaryFunction(form,fun) ==
form isnt ["LET",inits,:body] => form
for defs in tails inits repeat
def := first defs
atom def => nil -- no initializer
rplac(second def, FUNCALL(fun, second def))
for stmts in tails body repeat
rplac(first stmts, FUNCALL(fun, first stmts))
form
--%
++ List of macros used by the middle end to represent some
++ high level control structures.
-- NOTE: It is potentially dangerous to assume every occurrence of
-- element of $middleEndMacroList is actually a macro call
$middleEndMacroList ==
'(COLLECT REPEAT SUCHTHATCLAUSE THETA COLLECTV
COLLECTVEC THETA1 SPADREDUCE SPADDO)
middleEndExpand: %Form -> %Form
middleEndExpand x ==
isAtomicForm x => x
first x in $middleEndMacroList =>
middleEndExpand MACROEXPAND_-1 x
a := middleEndExpand first x
b := middleEndExpand rest x
EQ(a,first x) and EQ(b,rest x) => x
[a,:b]
-- A function is simple if it looks like a super combinator, and it
-- does not use its environment argument. They can be safely replaced
-- by more efficient (hopefully) functions.
getFunctionReplacement: %Symbol -> %Form
getFunctionReplacement name ==
GET(name, "SPADreplace")
++ remove any replacement info possibly associated with `name'.
clearReplacement name ==
REMPROP(name,"SPADreplace")
eqSubstAndCopy: (%List, %List, %Form) -> %Form
eqSubstAndCopy(args,parms,body) ==
SUBLIS(pairList(parms,args),body,KEYWORD::TEST,function EQ)
eqSubst: (%List, %List, %Form) -> %Form
eqSubst(args,parms,body) ==
NSUBLIS(pairList(parms,args),body,KEYWORD::TEST,function EQ)
++ returns true if `form' does not really induce computations.
isAtomicForm: %Form -> %Boolean
isAtomicForm form ==
atom form or first form = "QUOTE"
++ Walk `form' and replace simple functions as appropriate.
replaceSimpleFunctions form ==
isAtomicForm form => form
form is ["COND",:body] =>
mutateCONDFormWithUnaryFunction(form,"replaceSimpleFunctions")
form is ["LET",:.] =>
optLET mutateLETFormWithUnaryFunction(form,"replaceSimpleFunctions")
form is ["spadConstant","$",n] =>
null(op := getCapsuleDirectoryEntry n) => form
getFunctionReplacement op is ["XLAM",=nil,body]
and isAtomicForm body => body
-- Conservatively preserve object identity and storage
-- consumption by not folding non-atomic constant forms.
form
-- 1. process argument first.
for args in tails rest form repeat
arg' := replaceSimpleFunctions(arg := first args)
not EQ(arg',arg) =>
rplac(first args, arg')
-- 2. see if we know something about this function.
[fun,:args] := form
atom fun =>
null (fun' := getFunctionReplacement fun) => form
-- 2.1. the renaming case.
atom fun' =>
rplac(first form,fun')
NBUTLAST form
-- 2.2. the substitution case.
fun' is ["XLAM",parms,body] =>
-- Inline almost constant functions.
null parms => body
-- Identity function toos.
parms is [=body] => first args
-- conservatively approximate eager semantics
and/[isAtomicForm first as for as in tails args] =>
-- alpha rename before substitution.
newparms := [GENSYM() for p in parms]
body := eqSubstAndCopy(newparms,parms,body)
eqSubst(args,newparms,body)
-- get cute later.
form
form
fun' := replaceSimpleFunctions fun
not EQ(fun',fun) => rplac(first form,fun')
form
++ Replace all SPADCALLs to operations defined in the current
++ domain. Conditional operations are not folded.
foldSpadcall: %Form -> %Form
foldSpadcall form ==
isAtomicForm form => form
form is ["LET",inits,:body] =>
mutateLETFormWithUnaryFunction(form,"foldSpadcall")
form is ["COND",:stmts] =>
mutateCONDFormWithUnaryFunction(form,"foldSpadcall")
for args in tails rest form repeat
foldSpadcall first args
first form ^= "SPADCALL" => form
fun := lastNode form
fun isnt [["getShellEntry","$",slot]] => form
null (op := getCapsuleDirectoryEntry slot) => form
rplac(first fun, "$")
rplac(first form, op)
++ `defs' is a list of function definitions from the current domain.
++ Walk that list and replace references to unconditional operations
++ with their corresponding linkage names.
foldExportedFunctionReferences defs ==
for fun in defs repeat
foldSpadcall fun is [.,lamex] =>
rplac(third lamex, replaceSimpleFunctions third lamex)
defs
++ record optimizations permitted at level `level'.
setCompilerOptimizations level ==
level = nil => nil
INTEGERP level =>
if level = 0 then
-- explicit request for no optimization.
$optProclaim := false
$optReplaceSimpleFunctions := false
if level > 0 then
$optProclaim := true
$optReplaceSimpleFunctions := true
if level > 1 then
$optExportedFunctionReference := true
coreError '"unknown optimization level request"
--% Lisp backend support.
++ Proclaim the type of the capsule function `op' with signature `sig'.
++ Note that all capsule functions take an additional argument
++ standing for the domain of computation object.
proclaimCapsuleFunction(op,sig) ==
LAM_,EVALANDFILEACTQ
["DECLAIM",["FTYPE",
["FUNCTION",[:[vmType first d for d in tails rest sig],"%Shell"],
vmType first sig],op]] where
vmType d ==
$subdomain and d = "$" =>
-- We want accurate approximation for subdomains/superdomains
-- that are specialized and known to the VM.
(m := getVMType normalize $functorForm) = "%Thing" =>
getVMType normalize "$"
m
getVMType normalize d
normalize(d,top? == true) ==
d = "$" =>
not top? => "*"
-- If the representation is explicitly stated, use it. That way
-- we optimize abstractions just as well as builtins.
r := getRepresentation $e => normalize(r,top?)
-- Cope with old-style constructor definition
atom $functorForm => [$functorForm]
normalize($functorForm,top?)
atom d =>
top? => "%Thing"
getmode(d,$e) => "*"
d
[first d, :[normalize(first args,false) for args in tails rest d]]
++ Lisp back end compiler for ILAM with `name', formal `args', and `body'.
backendCompileILAM: (%Symbol,%List, %Code) -> %Symbol
backendCompileILAM(name,args,body) ==
args' := NLIST(#args, ["GENSYM"])
body' := eqSubst(args',args,body)
MAKEPROP(name,"ILAM",true)
setDynamicBinding(name,["LAMBDA",args',:body'])
name
$CLOSEDFNS := nil
MAKE_-CLOSEDFN_-NAME() ==
INTERNL($FUNNAME,'"!", STRINGIMAGE # $CLOSEDFNS)
backendCompileNEWNAM: %Form -> %Void
backendCompileNEWNAM x ==
isAtomicForm x => nil
atom(y := first x) =>
backendCompileNEWNAM rest x
if y = "CLOSEDFN" then
u := MAKE_-CLOSEDFN_-NAME()
PUSH([u,second x], $CLOSEDFNS)
RPLACA(x,"FUNCTION")
RPLACA(rest x,u)
backendCompileNEWNAM first x
backendCompileNEWNAM rest x
++ Lisp back end compiler for SLAM forms [namd,args,:body].
++ A SLAM form is one that is `functional' in the sense that
++ its values are cached, so that equal lists of argument values
++ yield equal values. The arguments-value pairs are stored
++ as alists.
backendCompileSLAM: (%Symbol,%List,%Code) -> %Symbol
backendCompileSLAM(name,args,body) ==
al := INTERNL(name,'";AL") -- name of the cache alist.
auxfn := INTERNL(name,'";") -- name of the worker function.
g1 := GENSYM() -- name for the parameter.
g2 := GENSYM() -- name for the cache value
u := -- body of the stub function
null args => [nil,[auxfn]]
null rest args => [[g1],[auxfn,g1]]
[g1,["APPLX", ["FUNCTION",auxfn], g1]]
arg := first u
app := second u
codePart1 := -- look up the value if it is already there
args ^= nil => [["SETQ", g2, ["assoc",g1,al]], ["CDR",g2]]
[al]
codePart2 := -- otherwise, compute it.
args ^= nil => [true,["SETQ",g2,app],["SETQ",al,[[g1,:g2],:al]],g2]
[true,["SETQ",al,app]]
lamex := ["LAM",arg,["PROG",[g2],
["RETURN",["COND",codePart1,codePart2]]]]
setDynamicBinding(al,nil) -- clear the cache
-- compile the worker function, first.
u := [auxfn,["LAMBDA",args,:body]]
COMP370 [u]
-- then compile the original function.
u := [name,lamex]
if $PrettyPrint then PRETTYPRINT u
COMP370 [u]
name
++ Same as backendCompileSPADSLAM, except that the cache is a hash
++ table. This backend compiler is used to compile constructors.
backendCompileSPADSLAM: (%Symbol,%List,%Code) -> %Symbol
backendCompileSPADSLAM(name,args,body) ==
al := INTERNL(name,'";AL") -- name of the cache hash table.
auxfn := INTERNL(name,'";") -- name of the worker function.
g1 := GENSYM() -- name of the worker function parameter
g2 := GENSYM() -- name for the cache value.
u :=
null args => [nil,nil,[auxfn]]
null rest args => [[g1],["devaluate",g1],[auxfn,g1]]
[g1,["devaluateList",g1],["APPLY",["FUNCTION",auxfn],g1]]
arg := first u
argtran := second u -- devaluate argument
app := third u
codePart1 := -- if value already computed, grab it.
null args => [al]
[["SETQ",g2,["assoc",argtran,al]], ["CDR",g2]]
codePart2 := -- otherwise compute it, and cache it.
-- Note: at most five values are cached.
null args => [true,["SETQ",al,app]]
[true,["SETQ",al,["cons5",["CONS",argtran, ["SETQ",g2,app]],al]],g2]
decl := -- declare the cache variable.
null args => nil
[g2]
lamex := ["LAM",arg,["LET",decl,["COND",codePart1,codePart2]]]
SETANDFILE(al,nil) -- define the global cache.
-- compile the worker function first.
u := [auxfn,["LAMBDA",args,:body]]
if $PrettyPrint then PRETTYPRINT u
COMP370 [u]
-- then compiler the stub (which is the user-visible constructor).
u := [name,lamex]
if $PrettyPrint then PRETTYPRINT u
COMP370 [u]
name
backendCompile2: %Code -> %Symbol
backendCompile2 code ==
code isnt [name,[type,args,:body],:junk] or junk ^= nil =>
systemError ['"parenthesis error in: ", code]
type = "SLAM" => backendCompileSLAM(name,args,body)
LASSQ(name,$clamList) => compClam(name,args,body,$clamList)
type = "SPADSLAM" => backendCompileSPADSLAM(name,args,body)
type = "ILAM" => backendCompileILAM(name,args,body)
body := [name,[type,args,:body]]
if $PrettyPrint then PRETTYPRINT body
if not $COMPILE then SAY '"No Compilation"
else COMP370 [body]
name
++ returns all fuild variables contained in `x'. Fuild variables are
++ identifiers starting with '$', except domain variable names.
backendFluidize x ==
IDENTP x and x ^= "$" and x ^= "$$" and
(PNAME x).0 = char "$" and not DIGITP((PNAME x).1) => x
isAtomicForm x => nil
first x = "FLUID" => second x
a := backendFluidize first x
b := backendFluidize rest x
a = nil => b
[a,:b]
$FluidVars := []
$LocalVars := []
$SpecialVars := []
++ push `x' into the list of local variables.
pushLocalVariable: %Symbol -> %List
pushLocalVariable x ==
x ^= "$" and (p := PNAME x).0 = char "$" and
p.1 ^= char "," and not DIGITP p.1 => nil
PUSH(x,$LocalVars)
--%
--% Middle Env to Back End Transformations.
--%
--% e ::=
--% (%ilConst <c> <type>) -- constant
--% (%ilInert <e> <type>) -- inert form
--% (%ilCtx <d> <type>) -- context
--% (%ilVar <n> <type>) -- variable
--% (%ilLisp <e> <type>) -- Lisp form
--% (%ilFun <e> <type>) -- function object
--% (%ilMm <e> <type>) -- modemap
--% (%ilLocal <n> <type>) -- local function
--% (%ilCtor <n> <type>) -- constructor
--% (%ilTag <e> <type>) -- tag of union object
--% (%ilVal <e> <type>) -- value of union object
--% (%ilCall <e...e> <type>) -- a call
--% (%ilXLAM <e> <type>) -- XLAM form
--% (%ilLAM <e> <type>) -- LAMBDA form
structure ILInsn ==
%ilConst(c,t) -- constant
%ilInert(e,t) -- inert form
%ilContext(e,t) -- context
%ilVar(n,t) -- variable
%ilCtor(n,t) -- constructor
%ilLocal(op,t) -- local function
%ilLisp(e,t) -- Lisp form
%ilModemap(e,t) -- exported function modemap
%ilUnionTag e -- union object tag
%ilUnionValue(e,t) -- union object value
%ilDeref(e,t) -- deref function pointer
%ilCall(e,t) -- call
%ilType(d,t) -- type instantiation request
%ilReturn(n,T,t) -- `return' expression
%ilExit(n,T,t) -- `exit' expression
++ Convert middle end IL forms to old back end forms.
il2OldForm x ==
atom x => x -- ideally should not happen
x is ["QUOTE",:.] => x -- idem.
case x of
%ilConst(c,.) => c
%ilInert(e,.) => e
%ilVar(n,.) => n
%ilCtor(n,.) => n
%ilContext(e,.) => e
%ilLisp(e,.) => e
%ilModemap(e,.) => e
%ilUnionTag(e,.) => ["CAR",il2OldForm e]
%ilUnionValue(e,.) => ["CAR",il2OldForm e]
%ilDeref(e,.) => ["applyFun",il2OldForm e]
%ilCall(e,.) =>
e is [["%ilLocal",op,:.],:.] =>
rplac(first e,op)
ilTransformInsns rest e
e
["call",:ilTransformInsns e]
otherwise => ilTransformInsns x
++ Subroutines of il2OldForm to walk sequence of IL instructions.
ilTransformInsns form ==
for insns in tails form repeat
rplac(first insns, il2OldForm first insns)
form
--%
++ Replace every middle end sub-forms in `x' with Lisp code.
mutateToBackendCode: %Form -> %Void
mutateToBackendCode x ==
isAtomicForm x => nil
-- temporarily have TRACELET report MAKEPROPs.
if (u := first x) = "MAKEPROP" and $TRACELETFLAG then
RPLACA(x,"MAKEPROP-SAY")
u in '(DCQ RELET PRELET SPADLET SETQ %LET) =>
if u ^= "DCQ" then
$NEWSPAD or $FUNAME in $traceletFunctions =>
nconc(x,$FUNNAME__TAIL)
RPLACA(x,"LETT")
$TRACELETFLAG => RPLACA(x,"/TRACE-LET")
u = "%LET" => RPLACA(x,"SPADLET")
mutateToBackendCode CDDR x
if not (u in '(SETQ RELET)) then
IDENTP second x => pushLocalVariable second x
second x is ["FLUID",:.] =>
PUSH(CADADR x, $FluidVars)
rplac(second x, CADADR x)
MAPC(function pushLocalVariable, LISTOFATOMS second x)
IDENTP u and GET(u,"ILAM") ^= nil =>
RPLACA(x, eval u)
mutateToBackendCode x
u in '(PROG LAMBDA) =>
newBindings := []
for y in second x repeat
not (y in $LocalVars) =>
$LocalVars := [y,:$LocalVars]
newBindings := [y,:newBindings]
res := mutateToBackendCode CDDR x
$LocalVars := REMOVE_-IF(function LAMBDA(y(), y in newBindings),
$LocalVars)
[u,second x,:res]
u = "DECLARE" => nil -- there is nothing to do convert there
mutateToBackendCode u
mutateToBackendCode rest x
skipDeclarations: %List -> %List
skipDeclarations form ==
while first form is ["DECLARE",:.] repeat
form := rest form
form
++ return the last node containing a declaration in form, otherwise nil.
lastDeclarationNode: %List -> %List
lastDeclarationNode form ==
while second form is ["DECLARE",:.] repeat
form := rest form
first form is ["DECLARE",:.] => form
nil
declareGlobalVariables: %List -> %List
declareGlobalVariables vars ==
["DECLARE",["SPECIAL",:vars]]
++ Generate Lisp code by lowering middle end defining form `x'.
++ x has the strucrure: <name, parms, stmt1, ...>
transformToBackendCode: %Form -> %Code
transformToBackendCode x ==
$FluidVars: fluid := nil
$LocalVars: fluid := nil
$SpecialVars: fluid := nil
x := middleEndExpand x
mutateToBackendCode CDDR x
body := skipDeclarations CDDR x
-- Make it explicitly a sequence of statements if it is not a one liner.
body :=
stmt := first body
null rest body and
(atom stmt or first stmt = "SEQ" or not CONTAINED("EXIT",stmt)) =>
body
[["SEQ",:body]]
$FluidVars := REMDUP nreverse $FluidVars
$LocalVars := S_-(S_-(REMDUP nreverse $LocalVars,$FluidVars),
LISTOFATOMS second x)
lvars := [:$FluidVars,:$LocalVars]
fluids := S_+($FluidVars,$SpecialVars)
body :=
fluids ^= nil =>
[["PROG",lvars,declareGlobalVariables fluids, ["RETURN",:body]]]
lvars ^= nil or CONTAINED("RETURN",body) =>
[["PROG",lvars,["RETURN",:body]]]
body
-- add reference parameters to the list of special variables.
fluids := S_+(backendFluidize second x, $SpecialVars)
lastdecl := lastDeclarationNode rest x
if lastdecl = nil then
RPLACD(rest x, body)
else
null fluids =>
RPLACD(lastdecl, body)
RPLACD(lastdecl, [declareGlobalVariables fluids,:body])
x
backendCompile1 x ==
fname := first x
$FUNNAME: local := fname
$FUNNAME__TAIL: local := [fname]
lamex := second x
$CLOSEDFNS: local := []
lamex := transformToBackendCode lamex
backendCompileNEWNAM lamex
-- Note that category constructors are evaluated before they
-- their compiled, so this noise is not very helpful.
if $verbose and FBOUNDP fname then
FORMAT(true,'"~&~%;;; *** ~S REDEFINED~%",fname)
[[fname,lamex],:$CLOSEDFNS]
backendCompile l ==
MAPCAR(function backendCompile2, MAPCAN(function backendCompile1,l))
compileFileQuietly path ==
quietlyIfInteractive COMPILE_-FILE path
++ Subroutine of compileConstructor1. Called to compile the body
++ of a category constructor definition.
compAndDefine l ==
_*COMP370_-APPLY_* := "PRINT-AND-EVAL-DEFUN"
backendCompile l
++ Subroutine of compileInteractive.
compQuietly fn ==
_*COMP370_-APPLY_* :=
$InteractiveMode =>
$compileDontDefineFunctions => "COMPILE-DEFUN"
"EVAL-DEFUN"
"PRINT-DEFUN"
quietlyIfInteractive backendCompile fn
compileQuietly fn ==
_*COMP370_-APPLY_* :=
$InteractiveMode =>
$compileDontDefineFunctions => "COMPILE-DEFUN"
"EVAL-DEFUN"
"PRINT-DEFUN"
quietlyIfInteractive COMP370 fn
|