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|
-- Copyright (c) 1991-2002, The Numerical Algorithms Group Ltd.
-- All rights reserved.
-- Copyright (C) 2007-2008, 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 i_-analy
namespace BOOT
-- Functions which require special handlers (also see end of file)
$specialOps := '(
ADEF AlgExtension _and _case COERCE COLLECT construct Declare DEF Dollar
equation error free has IF _is _isnt iterate _break %LET _local MDEF _or
pretend QUOTE REDUCE REPEAT _return SEQ TARGET tuple typeOf _where
_[_|_|_] %Macro %MLambda %Import %Export %Inline %With %Add)
$repeatLabel := NIL
$breakCount := 0
$anonymousMapCounter := 0
++ List of free variables in the current function
$freeVariables := []
++ List of bound variables in the current function
$boundVariables := []
--% Void stuff
voidValue() == '"()"
--% Handlers for Anonymous Function Definitions
upADEF t ==
t isnt [.,[vars,types,.,body],pred,.] => NIL
-- do some checking on what we got
for var in vars repeat
if not IDENTP(var) then throwKeyedMsg("S2IS0057",[var])
-- unabbreviate types
types := [(if t then evaluateType unabbrev t else NIL) for t in types]
-- we do not allow partial types
if isPartialMode(m := first types) then throwKeyedMsg("S2IS0058",[m])
-- we want everything to be declared or nothing. The exception is that
-- we do not require a target type since we will compute one anyway.
if null(m) and rest types then
m := first rest types
types' := rest rest types
else
types' := rest types
for type in types' repeat
if (type and null m) or (m and null type) then
throwKeyedMsg("S2IS0059",NIL)
if isPartialMode type then throwKeyedMsg("S2IS0058",[type])
-- $localVars: local := nil
-- $freeVars: local := nil
-- $env: local := [[nil]]
$compilingMap : local := true
-- if there is a predicate, merge it in with the body
if pred ^= true then body := ['IF,pred,body,'%noMapVal]
tar := getTarget t
null m and tar is ['Mapping,.,:argTypes] and (#vars = #argTypes) =>
if isPartialMode tar then throwKeyedMsg("S2IS0058",[tar])
evalTargetedADEF(t,vars,rest tar,body)
null m => evalUntargetedADEF(t,vars,types,body)
evalTargetedADEF(t,vars,types,body)
evalUntargetedADEF(t,vars,types,body) ==
-- recreate a parse form
if vars is [var]
then vars := var
else vars := ["tuple",:vars]
val := objNewWrap(["+->",vars,body],$AnonymousFunction)
putValue(t,val)
putModeSet(t,[objMode val])
evalTargetedADEF(t,vars,types,body) ==
$mapName : local := makeInternalMapName('"anonymousFunction",
#vars,$anonymousMapCounter,'"internal")
$anonymousMapCounter := 1 + $anonymousMapCounter
$compilingMap : local := true -- state that we are trying to compile
$mapThrowCount : local := 0 -- number of "return"s encountered
$mapReturnTypes : local := nil -- list of types from returns
$repeatLabel : local := nil -- for loops; see upREPEAT
$breakCount : local := 0 -- breaks from loops; ditto
-- now substitute formal names for the parm variables
-- this is used in the interpret-code case, but isn't so bad any way
-- since it makes the bodies look more like regular map bodies
sublist := [[var,:GENSYM()] for var in vars]
body := sublisNQ(sublist,body)
vars := [CDR v for v in sublist]
for m in CDR types for var in vars repeat
$env:= put(var,'mode,m,$env)
mkLocalVar($mapName,var)
for lvar in getLocalVars($mapName,body) repeat
mkLocalVar($mapName,lvar)
-- set up catch point for interpret-code mode
x := CATCH('mapCompiler,compileTargetedADEF(t,vars,types,body))
x = 'tryInterpOnly => mkInterpTargetedADEF(t,vars,types,body)
x
mkInterpTargetedADEF(t,vars,types,oldBody) ==
null first types =>
throwKeyedMsg("S2IS0056",NIL)
throwMessage '" map result type needed but not present."
arglCode := ["LIST",:[argCode for type in rest types for var in vars]]
where argCode() == ['putValueValue,['mkAtreeNode,MKQ var],
objNewCode(["wrap",var],type)]
put($mapName,'mapBody,oldBody,$e)
body := ['rewriteMap1,MKQ $mapName,arglCode,MKQ types]
compileADEFBody(t,vars,types,body,first types)
compileTargetedADEF(t,vars,types,body) ==
val := compileBody(body,CAR types)
computedResultType := objMode val
body := wrapMapBodyWithCatch flattenCOND objVal val
compileADEFBody(t,vars,types,body,computedResultType)
compileADEFBody(t,vars,types,body,computedResultType) ==
--+
$compiledOpNameList := [$mapName]
minivectorName := makeInternalMapMinivectorName(PNAME $mapName)
body := substitute(minivectorName,"$$$",body)
setDynamicBinding(minivectorName,LIST2REFVEC $minivector)
-- The use of the three variables $definingMap, $genValue and $compilingMap
-- is to cover the following cases:
--
-- $definingMap: This is set in analyzeMap and covers examples like:
-- addx x == ((y: Integer): Integer +-> x + y)
-- g := addx 10
-- g 3
-- i.e. we are storing the mapping as an object.
--
-- $compilingMap: This covers mappings which are created and applied "on the
-- "fly", for example:
-- [map(h +-> D(h, t), v) for v in [t]]
--
-- $genValue: This seems to be needed when we create a map as an argument
-- for a constructor, e.g.:
-- Dx: LODO(EXPR INT, f +-> D(f, x)) := D()
--
-- MCD 13/3/96
if not $definingMap and ($genValue or $compilingMap) then
fun := [$mapName,["LAMBDA",[:vars,'envArg],body]]
code := wrap compileInteractive fun
else
$freeVariables := []
$boundVariables := [minivectorName,:vars]
-- CCL does not support upwards funargs, so we check for any free variables
-- and pass them into the lambda as part of envArg.
body := checkForFreeVariables(body,"ALL")
fun := ["function",["LAMBDA",[:vars,'envArg],body]]
code := ["CONS", fun, ["VECTOR", :reverse $freeVariables]]
val := objNew(code,rt := ['Mapping,computedResultType,:rest types])
putValue(t,val)
putModeSet(t,[rt])
--% Handler for Algebraic Extensions
upAlgExtension t ==
-- handler for algebraic extension declaration. These are of
-- the form "a | a**2+1", and have the effect that "a" is declared
-- to be a simple algebraic extension, with respect to the given
-- polynomial, and given the value "a" in this type.
t isnt [op,var,eq] => nil
null $genValue => throwKeyedMsg("S2IS0001",NIL)
a := getUnname var
clearCmdParts ['propert,a] --clear properties of a
algExtension:= eq2AlgExtension eq
upmode := ['UnivariatePolynomial,a,$EmptyMode]
$declaredMode : local := upmode
putTarget(algExtension,upmode)
ms:= bottomUp algExtension
triple:= getValue algExtension
upmode:= resolveTMOrCroak(objMode(triple),upmode)
null (T:= coerceInteractive(triple,upmode)) =>
throwKeyedMsgCannotCoerceWithValue(objVal(triple),
objMode(triple),upmode)
newmode := objMode T
(field := resolveTCat(CADDR newmode,'(Field))) or
throwKeyedMsg("S2IS0002",[eq])
pd:= ['UnivariatePolynomial,a,field]
null (canonicalAE:= coerceInteractive(T,pd)) =>
throwKeyedMsgCannotCoerceWithValue(objVal T,objMode T,pd)
sae:= ['SimpleAlgebraicExtension,field,pd,objValUnwrap canonicalAE]
saeTypeSynonym := INTERN STRCONC('"SAE",STRINGIMAGE a)
saeTypeSynonymValue := objNew(sae,'(Domain))
fun := getFunctionFromDomain('generator,sae,NIL)
expr:= wrap SPADCALL(fun)
putHist(saeTypeSynonym,'value,saeTypeSynonymValue,$e)
putHist(a,'mode,sae,$e)
putHist(a,'value,T2:= objNew(expr,sae),$e)
clearDependencies(a,true)
if $printTypeIfTrue then
sayKeyedMsg("S2IS0003",NIL)
sayMSG concat ['%l,'" ",saeTypeSynonym,'" := ",
:prefix2String objVal saeTypeSynonymValue]
sayMSG concat ['" ",a,'" : ",saeTypeSynonym,'" := ",a]
putValue(op,T2)
putModeSet(op,[sae])
eq2AlgExtension eq ==
-- transforms "a=b" to a-b for processing
eq is [op,:l] and VECP op and (getUnname op='equation) =>
[mkAtreeNode "-",:l]
eq
--% Handlers for booleans
upand x ==
-- generates code for and forms. The second argument is only
-- evaluated if the first argument is true.
x isnt [op,term1,term2] => NIL
putTarget(term1,$Boolean)
putCallInfo(term1,"and",1,2)
putTarget(term2,$Boolean)
putCallInfo(term2,"and",2,2)
ms := bottomUp term1
ms isnt [=$Boolean] => nil -- use general modemap
$genValue =>
-- ??? we should find a way to check whether the
-- ??? the type of the second operand matters or not.
not objValUnwrap(getValue term1) => -- first operand is `false'
putValue(x,getValue term1)
putModeSet(x,ms)
-- first term is true, so look at the second one
ms := bottomUp term2
ms isnt [=$Boolean] => nil
putValue(x,getValue term2)
putModeSet(x,ms)
ms := bottomUp term2
ms isnt [=$Boolean] => nil -- use general modemap
-- generate an IF expression and let the rest of the code handle it
-- ??? In full generality, this is still incorrect. We should be
-- ??? looking up modemaps to see whether the interpretation is
-- ??? unique and the target type is Boolean before going on
-- ??? generating LISP IF-expression. -- gdr 2008/01/14
cond := [mkAtreeNode "=",mkAtree "false",term1]
putTarget(cond,$Boolean)
code := [mkAtreeNode "IF",cond,mkAtree "false",term2]
putTarget(code,$Boolean)
bottomUp code
putValue(x,getValue code)
putModeSet(x,ms)
upor x ==
-- generates code for or forms. The second argument is only
-- evaluated if the first argument is false.
x isnt [op,term1,term2] => NIL
putTarget(term1,$Boolean)
putCallInfo(term1,"or",1,2)
putTarget(term2,$Boolean)
putCallInfo(term2,"or",2,2)
ms := bottomUp term1
ms isnt [=$Boolean] => nil
$genValue =>
objValUnwrap(getValue term1) => -- first operand is true, we are done.
putValue(x,getValue term1)
putModeSet(x,ms)
-- first term is false, so look at the second one
ms := bottomUp term2
ms isnt [=$Boolean] => nil
putValue(x,getValue term2)
putModeSet(x,ms)
ms := bottomUp term2
ms isnt [=$Boolean] => nil
-- generate an IF expression and let the rest of the code handle it
cond := [mkAtreeNode "=",mkAtree "true",term1]
putTarget(cond,$Boolean)
-- ??? the following code generation is incorrect. -- gdr
code := [mkAtreeNode "IF",cond,mkAtree "true",term2]
putTarget(code,$Boolean)
bottomUp code
putValue(x,getValue code)
putModeSet(x,ms)
--% Handlers for case
++ subroutine of upcase. Handles the situation where `case' may
++ have been defined as a library function.
++ `op', `lhs' are VATs; `rhs' is unevaluated.
userDefinedCase(t is [op, lhs, rhs]) ==
-- We want to resolve the situation by general modemap selection.
-- So, we want to let bottomUp (which called us through upcase)
-- to continue the work. The way we do that is to return `nil'.
-- Therefore we need a VAT for `rhs' with sufficient information
-- to prevent bottomUp from trying to evaluate `rhs'.
putAtree(op, 'flagArgsPos, flagArguments("case",2))
r := mkAtreeNode $immediateDataSymbol
m := quasiquote rhs
putMode(r, m)
putValue(r, objNewWrap(MKQ rhs,m))
putModeSet(r, [m])
RPLACD(cdr t, [r]) -- fix up contained for rhs.
nil -- tell bottomUp to continue.
upcase t ==
t isnt [op,lhs,rhs] => nil
putCallInfo(lhs,"case",1,2)
bottomUp lhs
triple := getValue lhs
objMode(triple) isnt ['Union,:unionDoms] => userDefinedCase t
if (rhs' := isDomainValuedVariable(rhs)) then rhs := rhs'
if first unionDoms is [":",.,.] then
for i in 0.. for d in unionDoms repeat
if d is [":",=rhs,.] then rhstag := i
if NULL rhstag then error '"upcase: bad Union form"
$genValue =>
rhstag = first unwrap objVal triple => code := wrap 'TRUE
code := wrap NIL
code :=
["COND",
[["EQL",rhstag,["CAR",["unwrap",objVal triple]]],
''TRUE],
[''T,NIL]]
else
$genValue =>
t' := coerceUnion2Branch triple
rhs = objMode t' => code := wrap 'TRUE
code := wrap NIL
triple' := objNewCode(["wrap",objVal triple],objMode triple)
code :=
["COND",
[["EQUAL",MKQ rhs,["objMode",['coerceUnion2Branch,triple']]],
''TRUE],
[''T,NIL]]
putValue(op,objNew(code,$Boolean))
putModeSet(op,[$Boolean])
--% Handlers for TARGET
upTARGET t ==
-- Evaluates the rhs to a mode,which is used as the target type for
-- the lhs.
t isnt [op,lhs,rhs] => nil
-- do not (yet) support local variables on the rhs
(not $genValue) and or/[CONTAINED(var,rhs) for var in $localVars] =>
keyedMsgCompFailure("S2IC0010",[rhs])
$declaredMode: local := NIL
m:= evaluateType unabbrev rhs
not isLegitimateMode(m,NIL,NIL) => throwKeyedMsg("S2IE0004",[m])
categoryForm?(m) => throwKeyedMsg("S2IE0014",[m])
$declaredMode:= m
not atom(lhs) and putTarget(lhs,m)
ms := bottomUp lhs
first ms ^= m =>
throwKeyedMsg("S2IC0011",[first ms,m])
putValue(op,getValue lhs)
putModeSet(op,ms)
--% Handlers for COERCE
upCOERCE t ==
-- evaluate the lhs and then tries to coerce the result to the
-- mode which is the rhs.
-- previous to 5/16/89, this had the same semantics as
-- (lhs@rhs) :: rhs
-- this must be made explicit now.
t isnt [op,lhs,rhs] => nil
$useConvertForCoercions : local := true
-- do not (yet) support local variables on the rhs
(not $genValue) and or/[CONTAINED(var,rhs) for var in $localVars] =>
keyedMsgCompFailure("S2IC0006",[rhs])
$declaredMode: local := NIL
m := evaluateType unabbrev rhs
not isLegitimateMode(m,NIL,NIL) => throwKeyedMsg("S2IE0004",[m])
categoryForm?(m) => throwKeyedMsg("S2IE0014",[m])
$declaredMode:= m
-- 05/16/89 (RSS) following line commented out to give correct
-- semantic difference between :: and @
bottomUp lhs
type:=evalCOERCE(op,lhs,m)
putModeSet(op,[type])
evalCOERCE(op,tree,m) ==
-- the value of tree is coerced to mode m
-- this is not necessary, if the target property of tree was used
v := getValue tree
t1 := objMode(v)
if $genValue and t1 is ['Union,:.] then
v := coerceUnion2Branch v
t1 := objMode(v)
e := objVal(v)
value:=
t1=m => v
t2 :=
if isPartialMode m
then
$genValue and (t1 = $Symbol) and containsPolynomial m =>
resolveTM(['UnivariatePolynomial,objValUnwrap(v),$Integer],m)
resolveTM(t1,m)
else m
null t2 => throwKeyedMsgCannotCoerceWithValue(e,t1,m)
$genValue => coerceOrRetract(v,t2)
objNew(getArgValue(tree,t2),t2)
val:= value or throwKeyedMsgCannotCoerceWithValue(e,t1,m)
putValue(op,val)
objMode(val)
--% Handlers for COLLECT
upCOLLECT t ==
-- $compilingLoop variable insures that throw to interp-only mode
-- goes to the outermost loop.
$compilingLoop => upCOLLECT1 t
upCOLLECT0 t
upCOLLECT0 t ==
-- sets up catch point for interpret-code mode
$compilingLoop: local := true
ms:=CATCH('loopCompiler,upCOLLECT1 t)
ms = 'tryInterpOnly => interpOnlyCOLLECT t
ms
upCOLLECT1 t ==
t isnt [op,:itrl,body] => nil
-- upCOLLECT with compiled body
if (target := getTarget t) and not getTarget(body) then
if target is [agg,S] and agg in '(List Vector Stream InfiniteTuple) then
putTarget(body,S)
$interpOnly => interpCOLLECT(op,itrl,body)
isStreamCollect itrl => collectStream(t,op,itrl,body)
upLoopIters itrl
ms:= bottomUpCompile body
[m]:= ms
for itr in itrl repeat
itr is ["UNTIL", pred] => bottomUpCompilePredicate(pred,'"until")
mode:= ['Tuple,m]
evalCOLLECT(op,rest t,mode)
putModeSet(op,[mode])
upLoopIters itrl ==
-- type analyze iterator loop iterators
for iter in itrl repeat
iter is ["WHILE",pred] =>
bottomUpCompilePredicate(pred,'"while")
iter is ["SUCHTHAT",pred] =>
bottomUpCompilePredicate(pred,'"|")
iter is ["UNTIL",:.] =>
NIL -- handle after body is analyzed
iter is ["IN",index,s] =>
upLoopIterIN(iter,index,s)
iter is ["STEP",index,lower,step,:upperList] =>
upLoopIterSTEP(index,lower,step,upperList)
-- following is an optimization
typeIsASmallInteger(get(index,'mode,$env)) =>
RPLACA(iter,'ISTEP)
-- at this point, the AST may already be badly corrupted,
-- but better late than never.
throwKeyedMsg("S2IS0061",nil)
upLoopIterIN(iter,index,s) ==
iterMs := bottomUp s
null IDENTP index => throwKeyedMsg("S2IS0005",[index])
if $genValue and first iterMs is ['Union,:.] then
v := coerceUnion2Branch getValue s
m := objMode v
putValue(s,v)
putMode(s,m)
iterMs := [m]
putModeSet(s,iterMs)
-- transform segment variable into STEP
iterMs is [['Segment,.]] or iterMs is [['UniversalSegment,.]] =>
lower := [mkAtreeNode 'lo,s]
step := [mkAtreeNode 'incr, s]
upperList :=
CAAR(iterMs) = 'Segment => [[mkAtreeNode 'hi,s]]
NIL
upLoopIterSTEP(index,lower,step,upperList)
newIter := ['STEP,index,lower,step,:upperList]
RPLACA(iter,CAR newIter)
RPLACD(iter,CDR newIter)
iterMs isnt [['List,ud]] => throwKeyedMsg("S2IS0006",[index])
put(index,'mode,ud,$env)
mkLocalVar('"the iterator expression",index)
upLoopIterSTEP(index,lower,step,upperList) ==
null IDENTP index => throwKeyedMsg("S2IS0005",[index])
ltype := IFCAR bottomUpUseSubdomain(lower)
not (typeIsASmallInteger(ltype) or isEqualOrSubDomain(ltype,$Integer))=>
throwKeyedMsg("S2IS0007",['"lower"])
stype := IFCAR bottomUpUseSubdomain(step)
not (typeIsASmallInteger(stype) or isEqualOrSubDomain(stype,$Integer))=>
throwKeyedMsg("S2IS0008",NIL)
types := [ltype]
utype := nil
for upper in upperList repeat
utype := IFCAR bottomUpUseSubdomain(upper)
not (typeIsASmallInteger(utype) or isEqualOrSubDomain(utype,$Integer))=>
throwKeyedMsg("S2IS0007",['"upper"])
if utype then types := [utype, :types]
else types := [stype, :types]
type := resolveTypeListAny REMDUP types
put(index,'mode,type,$env)
mkLocalVar('"the iterator expression",index)
evalCOLLECT(op,[:itrl,body],m) ==
iters := [evalLoopIter itr for itr in itrl]
bod := getArgValue(body,computedMode body)
if bod isnt ['SPADCALL,:.] then bode := ['unwrap,bod]
code := timedOptimization asTupleNewCode0 ['COLLECT,:iters,bod]
if $genValue then code := wrap timedEVALFUN code
putValue(op,objNew(code,m))
falseFun(x) == nil
evalLoopIter itr ==
-- generate code for loop iterator
itr is ['STEP,index,lower,step,:upperList] =>
['STEP,getUnname index,getArgValue(lower,$Integer),
getArgValue(step,$Integer),
:[getArgValue(upper,$Integer) for upper in upperList]]
itr is ['ISTEP,index,lower,step,:upperList] =>
['ISTEP,getUnname index,getArgValue(lower,$SmallInteger),
getArgValue(step,$SmallInteger),
:[getArgValue(upper,$SmallInteger) for upper in upperList]]
itr is ['IN,index,s] =>
['IN,getUnname index,getArgValue(s,['List,get(index,'mode,$env)])]
(itr is [x,pred]) and (x in '(WHILE UNTIL SUCHTHAT)) =>
[x,getArgValue(pred,$Boolean)]
interpCOLLECT(op,itrl,body) ==
-- interpret-code mode COLLECT handler
$collectTypeList: local := NIL
$indexVars: local := NIL
$indexTypes: local := NIL
emptyAtree op
emptyAtree itrl
emptyAtree body
code := ['COLLECT,:[interpIter itr for itr in itrl],
interpCOLLECTbody(body,$indexVars,$indexTypes)]
value := timedEVALFUN code
t :=
null value => '(None)
last $collectTypeList
rm := ['Tuple,t]
value := [objValUnwrap coerceInteractive(objNewWrap(v,m),t)
for v in value for m in $collectTypeList]
putValue(op,objNewWrap(asTupleNew(#value, value),rm))
putModeSet(op,[rm])
interpIter itr ==
-- interpret loop iterator
itr is ['STEP,index,lower,step,:upperList] =>
$indexVars:= [getUnname index,:$indexVars]
[m]:= bottomUp lower
$indexTypes:= [m,:$indexTypes]
for up in upperList repeat bottomUp up
['STEP,getUnname index,getArgValue(lower,$Integer),
getArgValue(step,$Integer),
:[getArgValue(upper,$Integer) for upper in upperList]]
itr is ['ISTEP,index,lower,step,:upperList] =>
$indexVars:= [getUnname index,:$indexVars]
[m]:= bottomUp lower
$indexTypes:= [m,:$indexTypes]
for up in upperList repeat bottomUp up
['ISTEP,getUnname index,getArgValue(lower,$SmallInteger),
getArgValue(step,$SmallInteger),
:[getArgValue(upper,$SmallInteger) for upper in upperList]]
itr is ['IN,index,s] =>
$indexVars:=[getUnname index,:$indexVars]
[m]:= bottomUp s
m isnt ['List,um] => throwKeyedMsg("S2IS0009",[m])
$indexTypes:=[um,:$indexTypes]
['IN,getUnname index,getArgValue(s,m)]
(itr is [x,pred]) and (x in '(WHILE UNTIL SUCHTHAT)) =>
[x,interpLoop(pred,$indexVars,$indexTypes,$Boolean)]
interpOnlyCOLLECT t ==
-- called when compilation failed in COLLECT body, not in compiling map
$genValue: local := true
$interpOnly: local := true
upCOLLECT t
interpCOLLECTbody(expr,indexList,indexTypes) ==
-- generate code for interpret-code collect
['interpCOLLECTbodyIter,MKQ expr,MKQ indexList,['LIST,:indexList],
MKQ indexTypes]
interpCOLLECTbodyIter(exp,indexList,indexVals,indexTypes) ==
-- execute interpret-code collect body. keeps list of type of
-- elements in list in $collectTypeList.
emptyAtree exp
for i in indexList for val in indexVals for type in indexTypes repeat
put(i,'value,objNewWrap(val,type),$env)
[m]:=bottomUp exp
$collectTypeList:=
null $collectTypeList => [rm:=m]
[:$collectTypeList,rm:=resolveTT(m,last $collectTypeList)]
null rm => throwKeyedMsg("S2IS0010",NIL)
value:=
rm ^= m => coerceInteractive(getValue exp,rm)
getValue exp
objValUnwrap(value)
--% Stream Collect functions
isStreamCollect itrl ==
-- calls bottomUp on iterators and if any of them are streams
-- then whole shebang is a stream
isStream := false
for itr in itrl until isStream repeat
itr is ['IN,.,s] =>
iterMs := bottomUp s
iterMs is [['Stream,:.]] => isStream := true
iterMs is [['InfiniteTuple,:.]] => isStream := true
iterMs is [['UniversalSegment,:.]] => isStream := true
itr is ['STEP,.,.,.] => isStream := true
isStream
collectStream(t,op,itrl,body) ==
v := CATCH('loopCompiler,collectStream1(t,op,itrl,body))
v = 'tryInterpOnly => throwKeyedMsg("S2IS0011",NIL)
v
collectStream1(t,op,itrl,body) ==
$indexVars:local := NIL
upStreamIters itrl
if #$indexVars = 1 then mode:=collectOneStream(t,op,itrl,body)
else mode:=collectSeveralStreams(t,op,itrl,body)
putModeSet(op,[mode])
upStreamIters itrl ==
-- type analyze stream collect loop iterators
for iter in itrl repeat
iter is ['IN,index,s] =>
upStreamIterIN(iter,index,s)
iter is ['STEP,index,lower,step,:upperList] =>
upStreamIterSTEP(index,lower,step,upperList)
upStreamIterIN(iter,index,s) ==
iterMs := bottomUp s
-- transform segment variable into STEP
iterMs is [['Segment,.]] or iterMs is [['UniversalSegment,.]] =>
lower := [mkAtreeNode 'lo, s]
step := [mkAtreeNode 'incr, s]
upperList :=
CAAR(iterMs) = 'Segment => [[mkAtreeNode 'hi,s]]
NIL
upStreamIterSTEP(index,lower,step,upperList)
newIter := ['STEP,index,lower,step,:upperList]
RPLACA(iter,CAR newIter)
RPLACD(iter,CDR newIter)
(iterMs isnt [['List,ud]]) and (iterMs isnt [['Stream,ud]])
and (iterMs isnt [['InfinitTuple, ud]]) =>
throwKeyedMsg("S2IS0006",[index])
put(index,'mode,ud,$env)
mkLocalVar('"the iterator expression",index)
s :=
iterMs is [['List,ud],:.] =>
form:=[mkAtreeNode 'pretend, [mkAtreeNode 'COERCE,s,['Stream,ud]],
['InfiniteTuple, ud]]
bottomUp form
form
s
$indexVars:= [[index,:s],:$indexVars]
upStreamIterSTEP(index,lower,step,upperList) ==
null isEqualOrSubDomain(ltype := IFCAR bottomUpUseSubdomain(lower),
$Integer) => throwKeyedMsg("S2IS0007",['"lower"])
null isEqualOrSubDomain(stype := IFCAR bottomUpUseSubdomain(step),
$Integer) => throwKeyedMsg("S2IS0008",NIL)
for upper in upperList repeat
null isEqualOrSubDomain(IFCAR bottomUpUseSubdomain(upper),
$Integer) => throwKeyedMsg("S2IS0007",['"upper"])
put(index,'mode,type := resolveTT(ltype,stype),$env)
null type => throwKeyedMsg("S2IS0010", nil)
mkLocalVar('"the iterator expression",index)
s :=
null upperList =>
-- create the function that does the appropriate incrementing
genFun := 'generate
form := [mkAtreeNode genFun,
[[mkAtreeNode 'Dollar, ['IncrementingMaps,type],
mkAtreeNode 'incrementBy],step],lower]
bottomUp form
form
form := [mkAtreeNode 'SEGMENT,lower,first upperList]
putTarget(form,['Segment,type])
form := [mkAtreeNode 'construct,form]
putTarget(form,['List,['Segment,type]])
form := [mkAtreeNode 'expand,form]
putTarget(form,'(List (Integer)))
form:=[mkAtreeNode 'pretend, [mkAtreeNode 'COERCE,form,['Stream,$Integer]],
['InfiniteTuple, $Integer]]
bottomUp form
form
$indexVars:= [[index,:s],:$indexVars]
collectOneStream(t,op,itrl,body) ==
-- build stream collect for case of iterating over a single stream
-- In this case we don't need to build records
form := mkAndApplyPredicates itrl
bodyVec := mkIterFun(CAR $indexVars,body,$localVars)
form := [mkAtreeNode 'map,bodyVec,form]
bottomUp form
val := getValue form
m := objMode val
m isnt ['Stream, ud] and m isnt ['InfiniteTuple, ud] =>
systemError '"Not a Stream"
newVal := objNew(objVal val, ['InfiniteTuple, ud])
putValue(op,newVal)
objMode newVal
mkAndApplyPredicates itrl ==
-- for one index variable case for now. may generalize later
[indSet] := $indexVars
[.,:s] := indSet
for iter in itrl repeat
iter is ['WHILE,pred] =>
fun := 'filterWhile
predVec := mkIterFun(indSet,pred,$localVars)
s := [mkAtreeNode fun,predVec,s]
iter is ['UNTIL,pred] =>
fun := 'filterUntil
predVec := mkIterFun(indSet,pred,$localVars)
s := [mkAtreeNode fun,predVec,s]
iter is ['SUCHTHAT,pred] =>
fun := 'select
putTarget(pred,$Boolean)
predVec := mkIterFun(indSet,pred,$localVars)
s := [mkAtreeNode fun,predVec,s]
s
mkIterFun([index,:s],funBody,$localVars) ==
-- transform funBody into a lambda with index as the parameter
mode := objMode getValue s
mode isnt ['Stream, indMode] and mode isnt ['InfiniteTuple, indMode] =>
keyedSystemError('"S2GE0016", '("mkIterFun" "bad stream index type"))
put(index,'mode,indMode,$env)
mkLocalVar($mapName,index)
[m]:=bottomUpCompile funBody
mapMode := ['Mapping,m,indMode]
$freeVariables := []
$boundVariables := [index]
-- CCL does not support upwards funargs, so we check for any free variables
-- and pass them into the lambda as part of envArg.
body := checkForFreeVariables(getValue funBody,$localVars)
val:=['function,['LAMBDA,[index,'envArg],objVal body]]
vec := mkAtreeNode GENSYM()
putValue(vec,objNew(['CONS,val,["VECTOR",:reverse $freeVariables]],mapMode))
vec
checkForFreeVariables(v,locals) ==
-- v is the body of a lambda expression. The list $boundVariables is all the
-- bound variables, the parameter locals contains local variables which might
-- be free, or the token ALL, which means that any parameter is a candidate
-- to be free.
NULL v => v
SYMBOLP v =>
v="$$$" => v -- Placeholder for mini-vector
MEMQ(v,$boundVariables) => v
p := POSITION(v,$freeVariables) =>
["ELT","envArg",positionInVec(p,#($freeVariables))]
(locals = "ALL") or MEMQ(v,locals) =>
$freeVariables := [v,:$freeVariables]
["ELT","envArg",positionInVec(0,#($freeVariables))]
v
LISTP v =>
CDR(LASTTAIL v) => -- Must be a better way to check for a genuine list?
v
[op,:args] := v
LISTP op =>
-- Might have a mode at the front of a list, or be calling a function
-- which returns a function.
[checkForFreeVariables(op,locals),:[checkForFreeVariables(a,locals) for a in args]]
op = "LETT" => -- Expands to a SETQ.
["SETF",:[checkForFreeVariables(a,locals) for a in args]]
op = "COLLECT" => -- Introduces a new bound variable?
first(args) is ["STEP",var,:.] =>
$boundVariables := [var,:$boundVariables]
r := ["COLLECT",:[checkForFreeVariables(a,locals) for a in args]]
$boundVariables := delete(var,$boundVariables)
r
["COLLECT",:[checkForFreeVariables(a,locals) for a in args]]
op = "REPEAT" => -- Introduces a new bound variable?
first(args) is ["STEP",var,:.] =>
$boundVariables := [var,:$boundVariables]
r := ["REPEAT",:[checkForFreeVariables(a,locals) for a in args]]
$boundVariables := delete(var,$boundVariables)
r
["REPEAT",:[checkForFreeVariables(a,locals) for a in args]]
op = "%LET" =>
args is [var,form,name] =>
-- This is some bizarre %LET, not what one would expect in Common Lisp!
-- Treat var as a free variable, since it may be bound out of scope
-- if we are in a lambda within another lambda.
newvar :=
p := POSITION(var,$freeVariables) =>
["ELT","envArg",positionInVec(p,#($freeVariables))]
$freeVariables := [var,:$freeVariables]
["ELT","envArg",positionInVec(0,#($freeVariables))]
["SETF",newvar,checkForFreeVariables(form,locals)]
error "Non-simple variable bindings are not currently supported"
op = "PROG" =>
error "Non-simple variable bindings are not currently supported"
op = "LAMBDA" => v
op = "QUOTE" => v
op = "getValueFromEnvironment" => v
[op,:[checkForFreeVariables(a,locals) for a in args]]
v
positionInVec(p,l) ==
-- We cons up the free list, but need to keep positions consistent so
-- count from the end of the list.
l-p-1
collectSeveralStreams(t,op,itrl,body) ==
-- performs collects over several streams in parallel
$index: local := nil
[form,:zipType] := mkZipCode $indexVars
form := mkAndApplyZippedPredicates(form,zipType,itrl)
vec := mkIterZippedFun($indexVars,body,zipType,$localVars)
form := [mkAtreeNode 'map, vec, form]
bottomUp form
val := getValue form
m := objMode val
m isnt ['Stream, ud] and m isnt ['InfiniteTuple, ud] =>
systemError '"Not a Stream"
newVal := objNew(objVal val, ['InfiniteTuple, ud])
putValue(op,newVal)
objMode newVal
mkZipCode indexList ==
-- create interpreter form for turning a list of parallel streams
-- into a stream of nested record types. returns [form,:recordType]
#indexList = 2 =>
[[.,:s2],[.,:s1]] := indexList
t1 := CADR objMode getValue s1
t2 := CADR objMode getValue s2
zipType := ['Record,['_:,'part1,t1], ['_:,'part2,t2] ]
zipFun := [mkAtreeNode 'Dollar, ['MakeRecord,mkEvalable t1,
mkEvalable t2],
mkAtreeNode 'makeRecord]
form := [mkAtreeNode 'map,zipFun,s1,s2]
[form,:zipType]
[form,:zipType] := mkZipCode CDR indexList
[[.,:s],:.] := indexList
t := CADR objMode getValue s
zipFun := [mkAtreeNode 'Dollar, ['MakeRecord,mkEvalable t,
mkEvalable zipType],
mkAtreeNode 'makeRecord]
form := [mkAtreeNode 'map,zipFun,s,form]
zipType := ['Record,['_:,'part1,t],['_:,'part2,zipType]]
[form,:zipType]
mkAndApplyZippedPredicates (s,zipType,itrl) ==
-- for one index variable case for now. may generalize later
for iter in itrl repeat
iter is ['WHILE,pred] =>
predVec := mkIterZippedFun($indexVars,pred,zipType,$localVars)
s := [mkAtreeNode 'swhile,predVec,s]
iter is ['UNTIL,pred] =>
predVec := mkIterZippedFun($indexVars,pred,zipType,$localVars)
s := [mkAtreeNode 'suntil,predVec,s]
iter is ['SUCHTHAT,pred] =>
putTarget(pred,$Boolean)
predVec := mkIterZippedFun($indexVars,pred,zipType,$localVars)
s := [mkAtreeNode 'select,predVec,s]
s
mkIterZippedFun(indexList,funBody,zipType,$localVars) ==
-- transform funBody into a lamda with $index as the parameter
numVars:= #indexList
for [var,:.] in indexList repeat
funBody := subVecNodes(mkIterVarSub(var,numVars),var,funBody)
put($index,'mode,zipType,$env)
mkLocalVar($mapName,$index)
[m]:=bottomUpCompile funBody
mapMode := ['Mapping,m,zipType]
$freeVariables := []
$boundVariables := [$index]
-- CCL does not support upwards funargs, so we check for any free variables
-- and pass them into the lambda as part of envArg.
body :=
[checkForFreeVariables(form,$localVars) for form in getValue funBody]
val:=['function,['LAMBDA,[$index,'envArg],objVal body]]
vec := mkAtreeNode GENSYM()
putValue(vec,objNew(['CONS,val,["VECTOR",:reverse $freeVariables]],mapMode))
vec
subVecNodes(new,old,form) ==
ATOM form =>
(VECP form) and (form.0 = old) => new
form
[subVecNodes(new,old,CAR form), :subVecNodes(new,old,CDR form)]
mkIterVarSub(var,numVars) ==
n := iterVarPos var
n=2 =>
[mkAtreeNode "elt",mkNestedElts(numVars-2),mkAtreeNode 'part2]
n=1 =>
[mkAtreeNode "elt",mkNestedElts(numVars-2),mkAtreeNode 'part1]
[mkAtreeNode "elt",mkNestedElts(numVars-n),mkAtreeNode 'part1]
iterVarPos var ==
for [index,:.] in reverse $indexVars for i in 1.. repeat
index=var => return(i)
mkNestedElts n ==
n=0 => mkAtreeNode($index or ($index:= GENSYM()))
[mkAtreeNode "elt", mkNestedElts(n-1), mkAtreeNode 'part2]
--% Handlers for construct
upconstruct t ==
--Computes the common mode set of the construct by resolving across
--the argument list, and evaluating
t isnt [op,:l] => nil
dol := getAtree(op,'dollar)
tar := getTarget(op) or dol
null l => upNullList(op,l,tar)
tar is ['Record,:types] => upRecordConstruct(op,l,tar)
isTaggedUnion tar => upTaggedUnionConstruct(op,l,tar)
aggs := '(List)
if tar and PAIRP(tar) and ^isPartialMode(tar) then
CAR(tar) in aggs =>
ud :=
(l is [[realOp, :.]]) and (getUnname(realOp) = 'COLLECT) => tar
CADR tar
for x in l repeat if not getTarget(x) then putTarget(x,ud)
CAR(tar) in '(Matrix SquareMatrix RectangularMatrix) =>
vec := ['List,underDomainOf tar]
for x in l repeat if not getTarget(x) then putTarget(x,vec)
nargs := #l
argModeSetList:= [bottomUp putCallInfo(x,"construct",i,nargs)
for x in l for i in 1..]
dol and dol is [topType,:.] and not (topType in aggs) =>
(mmS:= selectMms(op,l,tar)) and (mS:= evalForm(op,getUnname op,l,mmS)) =>
putModeSet(op,mS)
NIL
(tar and tar is [topType,:.] and not (topType in aggs)) and
(mmS:= modemapsHavingTarget(selectMms(op,l,tar),tar)) and
(mS:= evalForm(op,getUnname op,l,mmS)) =>
putModeSet(op,mS)
eltTypes := replaceSymbols([first x for x in argModeSetList],l)
eltTypes is [['Tuple, td]] =>
mode := ['List, td]
evalTupleConstruct(op, l, mode, tar)
eltTypes is [['InfiniteTuple, td]] =>
mode := ['Stream, td]
evalInfiniteTupleConstruct(op, l, mode, tar)
if not isPartialMode(tar) and tar is ['List,ud] then
mode := ['List, resolveTypeListAny cons(ud,eltTypes)]
else mode := ['List, resolveTypeListAny eltTypes]
if isPartialMode tar then tar:=resolveTM(mode,tar)
evalconstruct(op,l,mode,tar)
modemapsHavingTarget(mmS,target) ==
-- returns those modemaps have the signature result matching the
-- given target
[mm for mm in mmS | ([[.,res,:.],:.] := mm) and res = target]
evalTupleConstruct(op,l,m,tar) ==
['List, ud] := m
code := ['APPEND,
:([["asTupleAsList", getArgValueOrThrow(x,['Tuple, ud])] for x in l])]
val :=
$genValue => objNewWrap(timedEVALFUN code,m)
objNew(code,m)
(val1 := coerceInteractive(val,tar or m)) =>
putValue(op,val1)
putModeSet(op,[tar or m])
putValue(op,val)
putModeSet(op,[m])
evalInfiniteTupleConstruct(op,l,m,tar) ==
['Stream, ud] := m
code := first [(getArgValue(x,['InfiniteTuple, ud]) or
throwKeyedMsg("S2IC0007",[['InifinteTuple, ud]])) for x in l]
val :=
$genValue => objNewWrap(timedEVALFUN code,m)
objNew(code,m)
if tar then val1 := coerceInteractive(val,tar) else val1 := val
val1 =>
putValue(op,val1)
putModeSet(op,[tar or m])
putValue(op,val)
putModeSet(op,[m])
evalconstruct(op,l,m,tar) ==
[agg,:.,underMode]:= m
code := ['LIST, :(argCode:=[(getArgValue(x,underMode) or
throwKeyedMsg("S2IC0007",[underMode])) for x in l])]
val :=
$genValue => objNewWrap(timedEVALFUN code,m)
objNew(code,m)
if tar then val1 := coerceInteractive(val,tar) else val1 := val
val1 =>
putValue(op,val1)
putModeSet(op,[tar or m])
putValue(op,val)
putModeSet(op,[m])
replaceSymbols(modeList,l) ==
-- replaces symbol types with their corresponding polynomial types
-- if not all type are symbols
not member($Symbol,modeList) => modeList
modeList is [a,:b] and and/[a=x for x in b] => modeList
[if m=$Symbol then getMinimalVarMode(objValUnwrap(getValue arg),
$declaredMode) else m for m in modeList for arg in l]
upNullList(op,l,tar) ==
-- handler for [] (empty list)
defMode :=
tar and tar is [a,b] and (a in '(Stream Vector List)) and
not isPartialMode(b) => ['List,b]
'(List (None))
val := objNewWrap(NIL,defMode)
tar and not isPartialMode(tar) =>
null (val' := coerceInteractive(val,tar)) =>
throwKeyedMsg("S2IS0013",[tar])
putValue(op,val')
putModeSet(op,[tar])
putValue(op,val)
putModeSet(op,[defMode])
upTaggedUnionConstruct(op,l,tar) ==
-- special handler for tagged union constructors
tar isnt [.,:types] => nil
#l ^= 1 => throwKeyedMsg("S2IS0051",[#l,tar])
bottomUp first l
obj := getValue first l
(code := coerceInteractive(getValue first l,tar)) or
throwKeyedMsgCannotCoerceWithValue(objVal obj, objMode obj,tar)
putValue(op,code)
putModeSet(op,[tar])
upRecordConstruct(op,l,tar) ==
-- special handler for record constructors
tar isnt [.,:types] => nil
argModes := nil
for arg in l repeat bottomUp arg
argCode :=
[(getArgValue(arg,type) or throwKeyedMsgCannotCoerceWithValue(
objVal getValue arg,objMode getValue arg,type))
for arg in l for ['_:,.,type] in types]
len := #l
code :=
(len = 1) => ["CONS", :argCode, '()]
(len = 2) => ["CONS",:argCode]
['VECTOR,:argCode]
if $genValue then code := wrap timedEVALFUN code
putValue(op,objNew(code,tar))
putModeSet(op,[tar])
--% Handlers for declarations
upDeclare t ==
t isnt [op,lhs,rhs] => nil
(not $genValue) and or/[CONTAINED(var,rhs) for var in $localVars] =>
keyedMsgCompFailure("S2IS0014",[lhs])
mode := evaluateType unabbrev rhs
mode = $Void => throwKeyedMsgSP("S2IS0015",NIL,op)
not isLegitimateMode(mode,nil,nil) => throwKeyedMsgSP("S2IE0004",[mode],op)
categoryForm?(mode) => throwKeyedMsgSP("S2IE0011",[mode, 'category],op)
packageForm?(mode) => throwKeyedMsgSP("S2IE0011",[mode, 'package],op)
getAtree(op,"callingFunction") =>
-- This isn't a real declaration, rather a field specification.
not IDENTP lhs => throwKeyedMsg("S2IE0020",nil)
-- ??? When we come to support field spec as type, change this.
putValue(op,objNewWrap([":",lhs,mode],mode))
putModeSet(op,[mode])
junk :=
lhs is ["free",["tuple",:vars]] or lhs is ['free,['LISTOF,:vars]] or
lhs is ["free",:vars] =>
for var in vars repeat declare(["free",var],mode)
lhs is ["local",["tuple",:vars]] or lhs is ["local",['LISTOF,:vars]] or
lhs is ["local",:vars] =>
for var in vars repeat declare(["local",var],mode)
lhs is ["tuple",:vars] or lhs is ["LISTOF",:vars] =>
for var in vars repeat declare(var,mode)
declare(lhs,mode)
putValue(op,objNewWrap(voidValue(), $Void))
putModeSet(op,[$Void])
declare(var,mode) ==
-- performs declaration.
-- 10/31/89: no longer coerces value to new declared type
if var is ['local,v] then
uplocalWithType(v,mode)
var := v
if var is ['free,v] then
upfreeWithType(v,mode)
var := v
not IDENTP(var) =>
throwKeyedMsg("S2IS0016",[STRINGIMAGE var])
var in '(% %%) => throwKeyedMsg("S2IS0050",[var])
if get(var,'isInterpreterFunction,$e) then
mode isnt ['Mapping,.,:args] =>
throwKeyedMsg("S2IS0017",[var,mode])
-- validate that the new declaration has the defined # of args
mapval := objVal get(var,'value,$e)
-- mapval looks like '(MAP (args . defn))
margs := CAADR mapval
-- if one args, margs is not a pair, just #1 or NIL
-- otherwise it looks like (tuple #1 #2 ...)
nargs :=
null margs => 0
PAIRP margs => -1 + #margs
1
nargs ^= #args => throwKeyedMsg("S2IM0008",[var])
if $compilingMap then mkLocalVar($mapName,var)
else clearDependencies(var,true)
isLocalVar(var) => put(var,'mode,mode,$env)
mode is ['Mapping,:.] => declareMap(var,mode)
v := get(var,'value,$e) =>
-- only allow this if either
-- - value already has given type
-- - new mode is same as old declared mode
objMode(v) = mode => putHist(var,'mode,mode,$e)
mode = get(var,'mode,$e) => NIL -- nothing to do
throwKeyedMsg("S2IS0052",[var,mode])
putHist(var,'mode,mode,$e)
declareMap(var,mode) ==
-- declare a Mapping property
(v:=get(var,'value,$e)) and objVal(v) isnt ['MAP,:.] =>
throwKeyedMsg("S2IS0019",[var])
isPartialMode mode => throwKeyedMsg("S2IM0004",NIL)
putHist(var,'mode,mode,$e)
getAndEvalConstructorArgument tree ==
triple := getValue tree
objMode triple = '(Domain) => triple
isWrapped objVal(triple) => triple
isLocalVar objVal triple => compFailure('" Local variable or parameter used in type")
objNewWrap(timedEVALFUN objVal(triple), objMode(triple))
replaceSharps(x,d) ==
-- replaces all sharps in x by the arguments of domain d
-- all replaces the triangle variables
SL:= NIL
for e in CDR d for var in $FormalMapVariableList repeat
SL:= CONS(CONS(var,e),SL)
x := subCopy(x,SL)
SL:= NIL
for e in CDR d for var in $TriangleVariableList repeat
SL:= CONS(CONS(var,e),SL)
subCopy(x,SL)
isDomainValuedVariable form ==
-- returns the value of form if form is a variable with a type value
IDENTP form and (val := (
get(form,'value,$InteractiveFrame) or _
(PAIRP($env) and get(form,'value,$env)) or _
(PAIRP($e) and get(form,'value,$e)))) and
(member(m := objMode(val),'((Domain) (Category)))
or conceptualType m = $Category) =>
objValUnwrap(val)
nil
evalCategory(d,c) ==
-- tests whether domain d has category c
isPartialMode d or ofCategory(d,c)
isOkInterpMode m ==
isPartialMode(m) => isLegitimateMode(m,nil,nil)
isValidType(m) and isLegitimateMode(m,nil,nil)
isLegitimateRecordOrTaggedUnion u ==
and/[x is [":",.,d] and isLegitimateMode(d,nil,nil) for x in u]
isPolynomialMode m ==
-- If m is a polynomial type this function returns a list of its
-- variables, and nil otherwise
m is [op,a,:rargs] =>
a := removeQuote a
MEMQ(op,'(Polynomial RationalFunction AlgebraicFunction Expression
ElementaryFunction LiouvillianFunction FunctionalExpression
CombinatorialFunction ))=> 'all
op = 'UnivariatePolynomial => LIST a
op = 'Variable => LIST a
MEMQ(op,'(MultivariatePolynomial DistributedMultivariatePolynomial
HomogeneousDistributedMultivariatePolynomial)) => a
NIL
NIL
containsPolynomial m ==
not PAIRP(m) => NIL
[d,:.] := m
d in $univariateDomains or d in $multivariateDomains or
d in '(Polynomial RationalFunction) => true
(m' := underDomainOf m) and containsPolynomial m'
containsVariables m ==
not PAIRP(m) => NIL
[d,:.] := m
d in $univariateDomains or d in $multivariateDomains => true
(m' := underDomainOf m) and containsVariables m'
listOfDuplicates l ==
l is [x,:l'] =>
x in l' => [x,:listOfDuplicates deleteAll(x,l')]
listOfDuplicates l'
-- The following function removes all occurrences of x from the list l
deleteAll(x,l) ==
null l => nil
x = CAR(l) => deleteAll(x,CDR l)
[first l,:deleteAll(x,rest l)]
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