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|
-- 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 i_-spec1
namespace BOOT
++ The `void' value object (an oxymoron). There really are constants.
$VoidValueObject := objNew(voidValue(), $Void)
$VoidCodeObject := objNew('(voidValue), $Void)
setValueToVoid t ==
putValue(t,$VoidValueObject)
putModeSet(t,[$Void])
setCodeToVoid t ==
putValue(t,$VoidCodeObject)
putModeSet(t,[$Void])
++ Interpreter macros
$InterpreterMacroAlist ==
'((%i . (complex 0 1))
(%e . (exp 1))
(%pi . (pi))
(SF . (DoubleFloat))
(%infinity . (infinity))
(%plusInfinity . (plusInfinity))
(%minusInfinity . (minusInfinity)))
-- Functions which require special handlers (also see end of file)
--% Handlers for map definitions
upDEF t ==
-- performs map definitions. value is thrown away
t isnt [op,def,pred,.] => nil
v:=addDefMap(["DEF",:def],pred)
null(LISTP(def)) or null(def) =>
keyedSystemError("S2GE0016",['"upDEF",'"bad map definition"])
mapOp := first def
if LISTP(mapOp) then
null mapOp =>
keyedSystemError("S2GE0016",['"upDEF",'"bad map definition"])
mapOp := first mapOp
put(mapOp,"value",v,$e)
setValueToVoid op
--% Handler for package calling and $ constants
++ Return non-nil if `form' designate a constant defined in the
++ domain designated by `domainForm'. More specifically, returns:
++ nil: no such constant
++ <%Mode>: the type of the constant.
++ T: too many constants designated by `form'.
constantInDomain?(form,domainForm) ==
opAlist := getOperationAlistFromLisplib first domainForm
key := opOf form
entryList := [entry for (entry := [.,.,.,k]) in LASSOC(key,opAlist)
| k in '(CONST ASCONST)]
entryList is [[sig,.,.,.]] => sig.target
#entryList > 2 => true
key = "One" => constantInDomain?(["1"], domainForm)
key = "Zero" => constantInDomain?(["0"], domainForm)
nil
++ Constant `c' of `type' is referenced from domain `d'; return its value
++ in the VAT `op'.
findConstantInDomain(op,c,type,d) ==
isPartialMode d => throwKeyedMsg("S2IS0020",NIL)
val :=
$genValue => wrap getConstantFromDomain([c],d)
["getConstantFromDomain",["LIST",MKQ c],MKQ d]
type := substitute(d,"$",type)
putValue(op,objNew(val,type))
putModeSet(op,[type])
upDollar t ==
-- Puts "dollar" property in atree node, and calls bottom up
t isnt [op,D,form] => nil
t2 := t
(not $genValue) and "or"/[CONTAINED(var,D) for var in $localVars] =>
keyedMsgCompFailure("S2IS0032",NIL)
D="Lisp" => upLispCall(op,form)
if VECP D and (SIZE(D) > 0) then D := D.0
t := evaluateType unabbrev D
categoryForm? t =>
throwKeyedMsg("S2IE0012", [t])
f := getUnname form
if f = $immediateDataSymbol then
f := objValUnwrap coerceInteractive(getValue form,$OutputForm)
if f = '(construct) then f := "nil"
atom form and (f ~= $immediateDataSymbol) =>
type := constantInDomain?([f],t) =>
type ~= true => findConstantInDomain(op,f,type,t)
-- Ambiguous constant. FIXME: try to narrow before giving up.
throwKeyedMsg("S2IB0008h",[f,t])
findUniqueOpInDomain(op,f,t)
nargs := #rest form
(ms := upDollarTuple(op, f, t, t2, rest form, nargs)) => ms
f ~= "construct" and null isOpInDomain(f,t,nargs) =>
throwKeyedMsg("S2IS0023",[f,t])
if (sig := findCommonSigInDomain(f,t,nargs)) then
for x in sig for y in form repeat
if x then putTarget(y,x)
putAtree(first form,"dollar",t)
ms := bottomUp form
f in '(One Zero) and cons? (ms) and first(ms) = $OutputForm =>
throwKeyedMsg("S2IS0021",[f,t])
putValue(op,getValue first form)
putModeSet(op,ms)
upDollarTuple(op, f, t, t2, args, nargs) ==
-- this function tries to find a tuple function to use
-- nargs = 1 and getUnname first args = "Tuple" => NIL
-- nargs = 1 and (ms := bottomUp first args) and ms is [["Tuple",.]] => NIL
null (singles := isOpInDomain(f,t,1)) => NIL
tuple := NIL
for [[.,arg], :.] in singles while null tuple repeat
if arg is ['Tuple,.] then tuple := arg
null tuple => NIL
[.,D,form] := t2
newArg := [mkAtreeNode "tuple",:args]
putTarget(newArg, tuple)
ms := bottomUp newArg
first ms ~= tuple => NIL
form := [first form, newArg]
putAtree(first form,"dollar",t)
ms := bottomUp form
putValue(op,getValue first form)
putModeSet(op,ms)
upLispCall(op,t) ==
-- process $Lisp calls
if atom t then code:=getUnname t else
[lispOp,:argl]:= t
null functionp lispOp.0 =>
throwKeyedMsg("S2IS0024",[lispOp.0])
for arg in argl repeat bottomUp arg
code:=[getUnname lispOp,
:[getArgValue(arg,computedMode arg) for arg in argl]]
code :=
$genValue => wrap timedEVALFUN code
code
rt := '(SExpression)
putValue(op,objNew(code,rt))
putModeSet(op,[rt])
--% Handlers for equation
upequation tree ==
-- only handle this if there is a target of Boolean
-- this should speed things up a bit
tree isnt [op,lhs,rhs] => NIL
$Boolean ~= getTarget(op) => NIL
null VECP op => NIL
-- change equation into '='
op.0 := "="
bottomUp tree
--% Handler for error
uperror t ==
-- when compiling a function, this merely inserts another argument
-- which is the name of the function.
not $compilingMap => NIL
t isnt [op,msg] => NIL
msgMs := bottomUp putCallInfo(msg,"error",1,1)
msgMs isnt [=$String] => NIL
RPLACD(t,[mkAtree object2String $mapName,msg])
bottomUp t
--% Handlers for free and local
upfree t ==
setCodeToVoid t
uplocal t ==
setCodeToVoid t
upfreeWithType(var,type) ==
sayKeyedMsg("S2IS0055",['"free",var])
var
uplocalWithType(var,type) ==
sayKeyedMsg("S2IS0055",['"local",var])
var
--% Handlers for has
uphas t ==
t isnt [op,type,prop] => nil
-- handler for category and attribute queries
type :=
x := elaborateForm type
getModeSet x is [m] and (conceptualType m = $Type or categoryForm? m) =>
val := objValUnwrap getValue x
$genValue => MKQ val
["devaluate",val]
throwKeyedMsg("S2IE0021",[type])
catCode :=
-- FIXME: when we come to support category valued variable
-- this code needs to be adapted.
prop := unabbrev prop
evaluateType0 prop => ["evaluateType", MKQ prop]
MKQ prop
code := ["NOT",["NULL",["newHasTest",type, catCode]]]
if $genValue then code := wrap timedEVALFUN code
putValue(op,objNew(code,$Boolean))
putModeSet(op,[$Boolean])
--hasTest(a,b) ==
-- newHasTest(a,b) --see NRUNFAST BOOT
--% Handlers for IF
upIF t ==
t isnt [op,cond,a,b] => nil
bottomUpPredicate(cond,'"if/when")
$genValue => interpIF(op,cond,a,b)
compileIF(op,cond,a,b,t)
compileIF(op,cond,a,b,t) ==
-- type analyzer for compiled case where types of both branches of
-- IF are resolved.
ms1 := bottomUp a
[m1] := ms1
b = "%noBranch" =>
evalIF(op,rest t,$Void)
putModeSet(op,[$Void])
b = "%noMapVal" =>
-- if this was a return statement, we take the mode to be that
-- of what is being returned.
if getUnname a = 'return then
ms1 := bottomUp second a
[m1] := ms1
evalIF(op,rest t,m1)
putModeSet(op,ms1)
ms2 := bottomUp b
[m2] := ms2
m:=
m2=m1 => m1
m2 = $Exit => m1
m1 = $Exit => m2
if m1 = $Symbol then
m1:=getMinimalVarMode(getUnname a,$declaredMode)
if m2 = $Symbol then
m2:=getMinimalVarMode(getUnname b,$declaredMode)
(r := resolveTTAny(m2,m1)) => r
rempropI($mapName,'localModemap)
rempropI($mapName,'localVars)
rempropI($mapName,'mapBody)
throwKeyedMsg("S2IS0026",[m2,m1])
evalIF(op,rest t,m)
putModeSet(op,[m])
evalIF(op,[cond,a,b],m) ==
-- generate code form compiled IF
elseCode:=
b="%noMapVal" =>
[[MKQ true, ["throwKeyedMsg",MKQ "S2IM0018",
["CONS",MKQ object2Identifier $mapName,NIL]]]]
b='%noBranch =>
$lastLineInSEQ => [[MKQ true,["voidValue"]]]
NIL
[[MKQ true,genIFvalCode(b,m)]]
code:=["COND",[getArgValue(cond,$Boolean),
genIFvalCode(a,m)],:elseCode]
triple:= objNew(code,m)
putValue(op,triple)
genIFvalCode(t,m) ==
-- passes type information down braches of IF statement
-- So that coercions can be performed on data at branches of IF.
m1 := computedMode t
m1=m => getArgValue(t,m)
code:=objVal getValue t
IFcodeTran(code,m,m1)
IFcodeTran(code,m,m1) ==
-- coerces values at branches of IF
null code => code
code is ["spadThrowBrightly",:.] => code
m1 = $Exit => code
code isnt ["COND",[p1,a1],[''T,a2]] =>
m = $Void => code
code' := coerceInteractive(objNew(quote2Wrapped code,m1),m) =>
getValueNormalForm code'
throwKeyedMsgCannotCoerceWithValue(quote2Wrapped code,m1,m)
a1:=IFcodeTran(a1,m,m1)
a2:=IFcodeTran(a2,m,m1)
['COND,[p1,a1],[''T,a2]]
interpIF(op,cond,a,b) ==
-- non-compiled version of IF type analyzer. Doesn't resolve accross
-- branches of the IF.
val:= getValue cond
val:= coerceInteractive(val,$Boolean) =>
objValUnwrap(val) => upIFgenValue(op,a)
b="%noBranch" => setValueToVoid op
upIFgenValue(op,b)
throwKeyedMsg("S2IS0031",NIL)
upIFgenValue(op,tree) ==
-- evaluates tree and transfers the results to op
ms:=bottomUp tree
val:= getValue tree
putValue(op,val)
putModeSet(op,ms)
--% Handlers for is
upis t ==
t isnt [op,a,pattern] => nil
$opIsIs : local := true
upisAndIsnt t
upisnt t ==
t isnt [op,a,pattern] => nil
$opIsIs : local := nil
upisAndIsnt t
upisAndIsnt(t:=[op,a,pattern]) ==
-- handler for "is" pattern matching
mS:= bottomUp a
mS isnt [m] =>
keyedSystemError("S2GE0016",['"upisAndIsnt",'"non-unique modeset"])
putPvarModes(removeConstruct pattern,m)
evalis(op,rest t,m)
putModeSet(op,[$Boolean])
putPvarModes(pattern,m) ==
-- Puts the modes for the pattern variables into $env
m isnt ["List",um] => throwKeyedMsg("S2IS0030",NIL)
for pvar in pattern repeat
IDENTP pvar => (null (pvar=$quadSymbol)) and put(pvar,'mode,um,$env)
pvar is ['_:,var] =>
null (var=$quadSymbol) and put(var,"mode",m,$env)
pvar is ['_=,var] =>
null (var=$quadSymbol) and put(var,"mode",um,$env)
putPvarModes(pvar,um)
evalis(op,[a,pattern],mode) ==
-- actually handles is and isnt
if $opIsIs
then fun := 'evalIsPredicate
else fun := 'evalIsntPredicate
if isLocalPred pattern then
code:= compileIs(a,pattern)
else code:=[fun,getArgValue(a,mode),
MKQ pattern,MKQ mode]
triple:=
$genValue => objNewWrap(timedEVALFUN code,$Boolean)
objNew(code,$Boolean)
putValue(op,triple)
isLocalPred pattern ==
-- returns true if the is predicate is to be compiled
for pat in pattern repeat
IDENTP pat and isLocalVar(pat) => return true
pat is [":",var] and isLocalVar(var) => return true
pat is ["=",var] and isLocalVar(var) => return true
compileIs(val,pattern) ==
-- produce code for compiled "is" predicate. makes pattern variables
-- into local variables of the function
vars:= NIL
for pat in rest pattern repeat
IDENTP(pat) and isLocalVar(pat) => vars:=[pat,:vars]
pat is [":",var] => vars:= [var,:vars]
pat is ["=",var] => vars:= [var,:vars]
predCode:=["%LET",g:=GENSYM(),["isPatternMatch",
getArgValue(val,computedMode val),MKQ removeConstruct pattern]]
for var in REMDUP vars repeat
assignCode:=[["%LET",var,["CDR",["ASSQ",MKQ var,g]]],:assignCode]
null $opIsIs =>
["COND",[["EQ",predCode,MKQ "failed"],["SEQ",:assignCode,MKQ 'T]]]
["COND",[["NOT",["EQ",predCode,MKQ "failed"]],["SEQ",:assignCode,MKQ 'T]]]
evalIsPredicate(value,pattern,mode) ==
--This function pattern matches value to pattern, and returns
--true if it matches, and false otherwise. As a side effect
--if the pattern matches then the bindings given in the pattern
--are made
pattern:= removeConstruct pattern
not ((valueAlist:=isPatternMatch(value,pattern))='failed) =>
for [id,:value] in valueAlist repeat
evalLETchangeValue(id,objNewWrap(value,get(id,'mode,$env)))
true
false
evalIsntPredicate(value,pattern,mode) ==
evalIsPredicate(value,pattern,mode) => false
true
removeConstruct pat ==
-- removes the "construct" from the beginning of patterns
if pat is ["construct",:p] then pat:=p
if pat is ["cons", a, b] then pat := [a, [":", b]]
atom pat => pat
RPLACA(pat,removeConstruct first pat)
RPLACD(pat,removeConstruct rest pat)
pat
isPatternMatch(l,pats) ==
-- perform the actual pattern match
$subs: local := NIL
isPatMatch(l,pats)
$subs
isPatMatch(l,pats) ==
null pats =>
null l => $subs
$subs:='failed
null l =>
null pats => $subs
pats is [[":",var]] =>
$subs := [[var],:$subs]
$subs:='failed
pats is [pat,:restPats] =>
IDENTP pat =>
$subs:=[[pat,:first l],:$subs]
isPatMatch(rest l,restPats)
pat is ["=",var] =>
p:=ASSQ(var,$subs) =>
first l = rest p => isPatMatch(rest l, restPats)
$subs:="failed"
$subs:="failed"
pat is [":",var] =>
n:=#restPats
m:=#l-n
m<0 => $subs:="failed"
ZEROP n => $subs:=[[var,:l],:$subs]
$subs:=[[var,:[x for x in l for i in 1..m]],:$subs]
isPatMatch(DROP(m,l),restPats)
isPatMatch(first l,pat) = "failed" => "failed"
isPatMatch(rest l,restPats)
keyedSystemError("S2GE0016",['"isPatMatch",
'"unknown form of is predicate"])
--% Handler for iterate
upiterate t ==
null $repeatBodyLabel => throwKeyedMsg("S2IS0029",['"iterate"])
$iterateCount := $iterateCount + 1
code := ["THROW",$repeatBodyLabel,'(voidValue)]
$genValue => THROW(eval $repeatBodyLabel,voidValue())
putValue(t,objNew(code,$Void))
putModeSet(t,[$Void])
--% Handler for break
upbreak t ==
t isnt [op,.] => nil
null $repeatLabel => throwKeyedMsg("S2IS0029",['"break"])
$breakCount := $breakCount + 1
code := ["THROW",$repeatLabel,'(voidValue)]
$genValue => THROW(eval $repeatLabel,voidValue())
putValue(op,objNew(code,$Void))
putModeSet(op,[$Void])
--% Handlers for %LET
up%LET t ==
-- analyzes and evaluates the righthand side, and does the variable
-- binding
t isnt [op,lhs,rhs] => nil
$declaredMode: local := NIL
cons? lhs =>
var:= getUnname first lhs
var = "construct" => upLETWithPatternOnLhs t
var = "QUOTE" => throwKeyedMsg("S2IS0027",['"A quoted form"])
upLETWithFormOnLhs(op,lhs,rhs)
var:= getUnname lhs
var = $immediateDataSymbol =>
-- following will be immediate data, so probably ok to not
-- specially format it
obj := objValUnwrap coerceInteractive(getValue lhs,$OutputForm)
throwKeyedMsg("S2IS0027",[obj])
var in '(% %%) => -- for history
throwKeyedMsg("S2IS0027",[var])
(IDENTP var) and not (var in '(true false elt QUOTE)) =>
var ~= (var' := unabbrev(var)) => -- constructor abbreviation
throwKeyedMsg("S2IS0028",[var,var'])
if get(var,'isInterpreterFunction,$e) then
putHist(var,'isInterpreterFunction,false,$e)
sayKeyedMsg("S2IS0049",['"Function",var])
else if get(var,'isInterpreterRule,$e) then
putHist(var,'isInterpreterRule,false,$e)
sayKeyedMsg("S2IS0049",['"Rule",var])
(m := isType rhs) => upLETtype(op,lhs,m)
transferPropsToNode(var,lhs)
if ( m:= getMode(lhs) ) then
$declaredMode := m
putTarget(rhs,m)
if (val := getValue lhs) and (objMode val = $Boolean) and
getUnname(rhs) = 'equation then putTarget(rhs,$Boolean)
(rhsMs:= bottomUp rhs) = [$Void] =>
throwKeyedMsg("S2IS0034",[var])
val:=evalLET(lhs,rhs)
putValue(op,val)
putModeSet(op,[objMode(val)])
throwKeyedMsg("S2IS0027",[var])
evalLET(lhs,rhs) ==
-- lhs is a vector for a variable, and rhs is the evaluated atree
-- for the value which is coerced to the mode of lhs
$useConvertForCoercions: local := true
v' := (v:= getValue rhs)
((not getMode lhs) and (getModeSet rhs is [.])) or
get(getUnname lhs,'autoDeclare,$env) =>
v:=
$genValue => v
objNew(getValueNormalForm v,objMode v)
evalLETput(lhs,v)
t1:= objMode v
t2' := (t2 := getMode lhs)
value:=
t1 = t2 =>
$genValue => v
objNew(getValueNormalForm v,objMode v)
if isPartialMode t2 then
if t1 = $Symbol and $declaredMode then
t1:= getMinimalVarMode(objValUnwrap v,$declaredMode)
t' := t2
null (t2 := resolveTM(t1,t2)) =>
if not t2 then t2 := t'
throwKeyedMsg("S2IS0035",[t1,t2])
null (v := getArgValue(rhs,t2)) =>
isWrapped(objVal v') and (v2:=coerceInteractive(v',$OutputForm)) =>
throwKeyedMsg("S2IS0036",[objValUnwrap v2,t2])
throwKeyedMsg("S2IS0037",[t2])
t2 and objNew(($genValue => wrap timedEVALFUN v ; v),t2)
value => evalLETput(lhs,value)
throwKeyedMsgCannotCoerceWithValue(objVal v,t1,getMode lhs)
evalLETput(lhs,value) ==
-- put value into the cell for lhs
name:= getUnname lhs
if not $genValue then
code:=
isLocalVar(name) =>
om := objMode(value)
dm := get(name,'mode,$env)
dm and not ((om = dm) or isSubDomain(om,dm) or
isSubDomain(dm,om)) =>
compFailure ['" The type of the local variable",
:bright name,'"has changed in the computation."]
if dm and isSubDomain(dm,om) then put(name,'mode,om,$env)
["%LET",name,objVal value,$mapName]
-- $mapName is set in analyzeMap
om := objMode value
dm := get(name, 'mode, $env) or objMode(get(name, 'value, $e))
dm and (null $compilingMap) and not(om = dm) and not(isSubDomain(om, dm)) =>
THROW('loopCompiler,'tryInterpOnly)
['unwrap,['evalLETchangeValue,MKQ name,
objNewCode(['wrap,objVal value],objMode value)]]
value:= objNew(code,objMode value)
isLocalVar(name) =>
if not get(name,'mode,$env) then put(name,'autoDeclare,'T,$env)
put(name,'mode,objMode(value),$env)
put(name,'automode,objMode(value),$env)
$genValue and evalLETchangeValue(name,value)
putValue(lhs,value)
upLETWithPatternOnLhs(t := [op,pattern,a]) ==
$opIsIs : local := true
[m] := bottomUp a
putPvarModes(pattern,m)
object := evalis(op,[a,pattern],m)
-- have to change code to return value of a
failCode :=
['spadThrowBrightly,['concat,
'" Pattern",['QUOTE,bright form2String pattern],
'"is not matched in assignment to right-hand side."]]
if $genValue
then
null objValUnwrap object => eval failCode
putValue(op,getValue a)
else
code := ['COND,[objVal object,objVal getValue a],[''T,failCode]]
putValue(op,objNew(code,m))
putModeSet(op,[m])
evalLETchangeValue(name,value) ==
-- write the value of name into the environment, clearing dependent
-- maps if its type changes from its last value
localEnv := cons? $env
clearCompilationsFlag :=
val:= (localEnv and get(name,'value,$env)) or get(name,'value,$e)
null val =>
not ((localEnv and get(name,'mode,$env)) or get(name,'mode,$e))
objMode val ~= objMode(value)
if clearCompilationsFlag then
clearDependencies(name,true)
if localEnv and isLocalVar(name)
then $env:= putHist(name,'value,value,$env)
else putIntSymTab(name,'value,value,$e)
objVal value
upLETWithFormOnLhs(op,lhs,rhs) ==
-- bottomUp for assignment to forms (setelt, table or tuple)
lhs' := getUnnameIfCan lhs
rhs' := getUnnameIfCan rhs
lhs' = "tuple" =>
rhs' ~= "tuple" => throwKeyedMsg("S2IS0039",NIL)
#(lhs) ~= #(rhs) => throwKeyedMsg("S2IS0038",NIL)
-- generate a sequence of assignments, using local variables
-- to first hold the assignments so that things like
-- (t1,t2) := (t2,t1) will work.
seq := []
temps := [GENSYM() for l in rest lhs]
for lvar in temps repeat mkLocalVar($mapName,lvar)
for l in reverse rest lhs for t in temps repeat
transferPropsToNode(getUnname l,l)
let := mkAtreeNode "%LET"
t' := mkAtreeNode t
if m := getMode(l) then putMode(t',m)
seq := cons([let,l,t'],seq)
for t in temps for r in reverse rest rhs
for l in reverse rest lhs repeat
let := mkAtreeNode "%LET"
t' := mkAtreeNode t
if m := getMode(l) then putMode(t',m)
seq := cons([let,t',r],seq)
seq := cons(mkAtreeNode 'SEQ,seq)
ms := bottomUp seq
putValue(op,getValue seq)
putModeSet(op,ms)
rhs' = "tuple" => throwKeyedMsg("S2IS0039",NIL)
tree:= seteltable(lhs,rhs) => upSetelt(op,lhs,tree)
throwKeyedMsg("S2IS0060", NIL)
-- upTableSetelt(op,lhs,rhs)
seteltable(lhs is [f,:argl],rhs) ==
-- produces the setelt form for trees such as "l.2:= 3"
null (g := getUnnameIfCan f) => NIL
g="elt" => altSeteltable [:argl, rhs]
get(g,'value,$e) is [expr,:.] and isMapExpr expr => NIL
transferPropsToNode(g,f)
getValue(lhs) or getMode(lhs) =>
f is [f',:argl'] => altSeteltable [f',:argl',:argl,rhs]
altSeteltable [:lhs,rhs]
NIL
altSeteltable args ==
for x in args repeat bottomUp x
newOps := [mkAtreeNode "setelt", mkAtreeNode "set!"]
form := NIL
-- first look for exact matches for any of the possibilities
while null form for newOp in newOps repeat
if selectMms(newOp, args, NIL) then form := [newOp, :args]
-- now try retracting arguments after the first
while null form and ( "and"/[retractAtree(a) for a in rest args] ) repeat
while null form for newOp in newOps repeat
if selectMms(newOp, args, NIL) then form := [newOp, :args]
form
upSetelt(op,lhs,tree) ==
-- type analyzes implicit setelt forms
var:=opOf lhs
transferPropsToNode(getUnname var,var)
if (m1:=getMode var) then $declaredMode:= m1
if m1 or ((v1 := getValue var) and (m1 := objMode v1)) then
putModeSet(var,[m1])
ms := bottomUp tree
putValue(op,getValue tree)
putModeSet(op,ms)
upTableSetelt(op,lhs is [htOp,:args],rhs) ==
-- called only for undeclared, uninitialized table setelts
("*" = (PNAME getUnname htOp).0) and (1 ~= # args) =>
throwKeyedMsg("S2IS0040",NIL)
# args ~= 1 =>
throwKeyedMsg("S2IS0041",[[getUnname htOp,'".[",
getUnname first args,
['",",getUnname arg for arg in rest args],'"]"]])
keyMode := '(Any)
putMode (htOp,['Table,keyMode,'(Any)])
-- if we are to use a new table, we must call the "table"
-- function to give it an initial value.
bottomUp [mkAtreeNode "%LET",htOp,[mkAtreeNode 'table]]
tableCode := objVal getValue htOp
r := upSetelt(op, lhs, [mkAtreeNode "setelt",:lhs,rhs])
$genValue => r
-- construct code
t := getValue op
putValue(op,objNew(['PROGN,tableCode,objVal t],objMode t))
r
unVectorize body ==
-- transforms from an atree back into a tree
VECP body =>
name := getUnname body
name ~= $immediateDataSymbol => name
objValUnwrap getValue body
atom body => body
body is [op,:argl] =>
newOp:=unVectorize op
if newOp = 'SUCHTHAT then newOp := "|"
if newOp = 'COERCE then newOp := "::"
if newOp = 'Dollar then newOp := "$elt"
[newOp,:unVectorize argl]
systemErrorHere ["unVectorize",body]
isType t ==
-- Returns the evaluated type if t is a tree representing a type,
-- and NIL otherwise
op:=opOf t
VECP op =>
isMap(op:= getUnname op) => NIL
op = 'Mapping and cons? t =>
argTypes := [isType type for type in rest t]
"or"/[null type for type in argTypes] => nil
['Mapping, :argTypes]
isLocalVar(op) => NIL
d := isDomainValuedVariable op => d
type:=
-- next line handles subscripted vars
(abbreviation?(op) or (op = 'typeOf) or
constructor?(op) or (op in '(Record Union Enumeration))) and
unabbrev unVectorize t
type and evaluateType type
d := isDomainValuedVariable op => d
NIL
upLETtype(op,lhs,type) ==
-- performs type assignment
opName:= getUnname lhs
(not $genValue) and "or"/[CONTAINED(var,type) for var in $localVars] =>
compFailure ['" Cannot compile type assignment to",:bright opName]
mode := conceptualType type
val:= objNew(type,mode)
if isLocalVar(opName) then put(opName,'value,val,$env)
else putHist(opName,'value,val,$e)
putValue(op,val)
-- have to fix the following
putModeSet(op,[mode])
assignSymbol(symbol, value, domain) ==
-- Special function for binding an interpreter variable from within algebra
-- code. Does not do the assignment and returns nil, if the variable is
-- already assigned
val := get(symbol, 'value, $e) => nil
obj := objNew(wrap value, devaluate domain)
put(symbol, 'value, obj, $e)
true
--% Handler for Interpreter Macros
getInterpMacroNames() ==
names := [n for [n,:.] in $InterpreterMacroAlist]
if (e := CAAR $InteractiveFrame) and (m := assoc("--macros--",e)) then
names := append(names,[n for [n,:.] in rest m])
MSORT names
isInterpMacro name ==
-- look in local and then global environment for a macro
null IDENTP name => NIL
name in $specialOps => NIL
(m := get("--macros--",name,$env)) => m
(m := get("--macros--",name,$e)) => m
(m := get("--macros--",name,$InteractiveFrame)) => m
-- $InterpreterMacroAlist will probably be phased out soon
(sv := assoc(name,$InterpreterMacroAlist)) => CONS(NIL,rest sv)
NIL
--% Handlers for prefix QUOTE
upQUOTE t ==
t isnt [op,expr] => NIL
ms:= list
m:= getBasicMode expr => m
IDENTP expr =>
-- $useSymbolNotVariable => $Symbol
getTarget t = $Identifier => $Identifier
['Variable,expr]
$InputForm
evalQUOTE(op,[expr],ms)
putModeSet(op,ms)
evalQUOTE(op,[expr],[m]) ==
triple:=
$genValue => objNewWrap(expr,m)
objNew(['QUOTE,expr],m)
putValue(op,triple)
--% Quasiquotation
up_[_|_|_] t ==
t isnt [op, x] => nil
mode := getTypeOfSyntax x
putValue(op, objNewWrap(x, mode))
putModeSet(op, [mode])
--% Handler for pretend
uppretend t ==
t isnt [op,expr,type] => NIL
mode := evaluateType unabbrev type
not isValidType(mode) => throwKeyedMsg("S2IE0004",[mode])
bottomUp expr
putValue(op,objNew(objVal getValue expr,mode))
putModeSet(op,[mode])
--% Handlers for REDUCE
getReduceFunction(op,type,result, locale) ==
-- return the function cell for operation with the signature
-- (type,type) -> type, possible from locale
if type is ['Variable,var] then
args := [arg := mkAtreeNode var,arg]
putValue(arg,objNewWrap(var,type))
else
args := [arg := mkAtreeNode "%1",arg]
if type=$Symbol then putValue(arg,objNewWrap("%1",$Symbol))
putModeSet(arg,[type])
vecOp:=mkAtreeNode op
transferPropsToNode(op,vecOp)
if locale then putAtree(vecOp,'dollar,locale)
mmS:= selectMms(vecOp,args,result)
mm:= or/[mm for (mm:=[[.,:sig],fun,cond]) in mmS |
(isHomogeneousArgs sig) and "and"/[null c for c in cond]]
null mm => 'failed
[[dc,:sig],fun,:.]:=mm
dc='local => [MKQ [fun,:'local],:first sig]
dcVector := evalDomain dc
$compilingMap =>
k := NRTgetMinivectorIndex(
NRTcompiledLookup(op,sig,dcVector),op,sig,dcVector)
['ELT,"$$$",k] --$$$ denotes minivector
env:=
NRTcompiledLookup(op,sig,dcVector)
MKQ env
isHomogeneous sig ==
--return true if sig describes a homogeneous binary operation
sig.0=sig.1 and sig.1=sig.2
isHomogeneousArgs sig ==
--return true if sig describes a homogeneous binary operation
sig.1=sig.2
--% Handlers for REPEAT
transformREPEAT [:itrl,body] ==
-- syntactic transformation of repeat iterators, called from mkAtree2
iterList:=[:iterTran1 for it in itrl] where iterTran1() ==
it is ["STEP",index,lower,step,:upperList] =>
[["STEP",index,mkAtree1 lower,mkAtree1 step,:[mkAtree1 upper
for upper in upperList]]]
it is ["IN",index,s] =>
[['IN,index,mkAtree1 s]]
it is ["ON",index,s] =>
[['IN,index,mkAtree1 ['tails,s]]]
it is ["WHILE",b] =>
[["WHILE",mkAtree1 b]]
it is ["|",pred] =>
[["SUCHTHAT",mkAtree1 pred]]
it is [op,:.] and (op in '(VALUE UNTIL)) => nil
bodyTree:=mkAtree1 body
iterList:=NCONC(iterList,[:iterTran2 for it in itrl]) where iterTran2() ==
it is ["STEP",:.] => nil
it is ["IN",:.] => nil
it is ["ON",:.] => nil
it is ["WHILE",:.] => nil
it is [op,b] and (op in '(UNTIL VALUE)) =>
[[op,mkAtree1 b]]
it is ['_|,pred] => nil
keyedSystemError("S2GE0016",
['"transformREPEAT",'"Unknown type of iterator"])
[:iterList,bodyTree]
upREPEAT t ==
-- REPEATS always return void() of Void
-- assures throw to interpret-code mode goes to outermost loop
$repeatLabel : local := MKQ GENSYM()
$breakCount : local := 0
$repeatBodyLabel : local := MKQ GENSYM()
$iterateCount : local := 0
$compilingLoop => upREPEAT1 t
upREPEAT0 t
upREPEAT0 t ==
-- sets up catch point for interp-only mode
$compilingLoop: local := true
ms := CATCH('loopCompiler,upREPEAT1 t)
ms = 'tryInterpOnly => interpOnlyREPEAT t
ms
upREPEAT1 t ==
-- repeat loop handler with compiled body
-- see if it has the expected form
t isnt [op,:itrl,body] => NIL
-- determine the mode of the repeat loop. At the moment, if there
-- there are no iterators and there are no "break" statements, then
-- the return type is Exit, otherwise Void.
repeatMode :=
null(itrl) and ($breakCount=0) => $Void
$Void
-- if interpreting, go do that
$interpOnly => interpREPEAT(op,itrl,body,repeatMode)
-- analyze iterators and loop body
upLoopIters itrl
bottomUpCompile body
-- now that the body is analyzed, we should know everything that
-- is in the UNTIL clause
for itr in itrl repeat
itr is ["UNTIL", pred] => bottomUpCompilePredicate(pred,'"until")
-- now go do it
evalREPEAT(op,rest t,repeatMode)
putModeSet(op,[repeatMode])
evalREPEAT(op,[:itrl,body],repeatMode) ==
-- generate code for loop
bodyMode := computedMode body
bodyCode := getArgValue(body,bodyMode)
if $iterateCount > 0 then
bodyCode := ["CATCH",$repeatBodyLabel,bodyCode]
code := ['REPEAT,:[evalLoopIter itr for itr in itrl], bodyCode]
if repeatMode = $Void then code := ['OR,code,'(voidValue)]
code := timedOptimization code
if $breakCount > 0 then code := ['CATCH,$repeatLabel,code]
val:=
$genValue =>
timedEVALFUN code
objNewWrap(voidValue(),repeatMode)
objNew(code,repeatMode)
putValue(op,val)
interpOnlyREPEAT t ==
-- interpret-code mode call to upREPEAT
$genValue: local := true
$interpOnly: local := true
upREPEAT1 t
interpREPEAT(op,itrl,body,repeatMode) ==
-- performs interpret-code repeat
$indexVars: local := NIL
$indexTypes: local := NIL
code :=
-- we must insert a CATCH for the iterate clause
["REPEAT",:[interpIter itr for itr in itrl],
["CATCH",$repeatBodyLabel,interpLoop(body,$indexVars,
$indexTypes,nil)]]
SPADCATCH(eval $repeatLabel,timedEVALFUN code)
val:= objNewWrap(voidValue(),repeatMode)
putValue(op,val)
putModeSet(op,[repeatMode])
interpLoop(expr,indexList,indexTypes,requiredType) ==
-- generates code for interp-only repeat body
['interpLoopIter,MKQ expr,MKQ indexList,["LIST",:indexList],
MKQ indexTypes, MKQ requiredType]
interpLoopIter(exp,indexList,indexVals,indexTypes,requiredType) ==
-- call interpreter on exp with loop vars in indexList with given
-- values and types, requiredType is used from interpCOLLECT
-- to indicate the required type of the result
emptyAtree exp
for i in indexList for val in indexVals for type in indexTypes repeat
put(i,'value,objNewWrap(val,type),$env)
bottomUp exp
v:= getValue exp
val :=
null requiredType => v
coerceInteractive(v,requiredType)
null val =>
throwKeyedMsgCannotCoerceWithValue(objVal v,objMode v,requiredType)
objValUnwrap val
--% Handler for return
upreturn t ==
-- make sure we are in a user function
t isnt [op,val] => NIL
(null $compilingMap) and (null $interpOnly) =>
throwKeyedMsg("S2IS0047",NIL)
if $mapTarget then putTarget(val,$mapTarget)
bottomUp val
if $mapTarget
then
val' := getArgValue(val, $mapTarget)
m := $mapTarget
else
val' := getValueNormalForm getValue val
m := computedMode val
cn := mapCatchName $mapName
$mapReturnTypes := insert(m, $mapReturnTypes)
$mapThrowCount := $mapThrowCount + 1
-- if $genValue then we are interpreting the map
$genValue => THROW(cn,objNewWrap(removeQuote val',m))
putValue(op,objNew(['THROW,MKQ cn,val'],m))
putModeSet(op,[$Exit])
--% Handler for SEQ
upSEQ u ==
-- assumes that exits were translated into if-then-elses
-- handles flat SEQs and embedded returns
u isnt [op,:args] => NIL
if (target := getTarget(op)) then putTarget(last args, target)
for x in args repeat bottomUp x
null (m := computedMode last args) =>
keyedSystemError("S2GE0016",['"upSEQ",
'"last line of SEQ has no mode"])
evalSEQ(op,args,m)
putModeSet(op,[m])
evalSEQ(op,args,m) ==
-- generate code for SEQ
[:argl,last] := args
val:=
$genValue => getValue last
bodyCode := nil
for x in args repeat
(m1 := computedMode x) and (m1 ~= '$ThrowAwayMode) =>
(av := getArgValue(x,m1)) ~= voidValue() =>
bodyCode := [av,:bodyCode]
code:=
bodyCode is [c] => c
['PROGN,:reverse bodyCode]
objNew(code,m)
putValue(op,val)
--% Handlers for tuple
uptuple 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 => upNullTuple(op,l,tar)
isTaggedUnion tar => upTaggedUnionConstruct(op,l,tar)
aggs := '(List)
if tar and cons?(tar) and not isPartialMode(tar) then
first(tar) in aggs =>
ud := second tar
for x in l repeat if not getTarget(x) then putTarget(x,ud)
first(tar) in '(Matrix SquareMatrix RectangularMatrix) =>
vec := ['List,underDomainOf tar]
for x in l repeat if not getTarget(x) then putTarget(x,vec)
argModeSetList:= [bottomUp x for x in l]
eltTypes := replaceSymbols([first x for x in argModeSetList],l)
if not isPartialMode(tar) and tar is ['Tuple,ud] then
mode := ['Tuple, resolveTypeListAny cons(ud,eltTypes)]
else mode := ['Tuple, resolveTypeListAny eltTypes]
if isPartialMode tar then tar:=resolveTM(mode,tar)
evalTuple(op,l,mode,tar)
evalTuple(op,l,m,tar) ==
[agg,:.,underMode]:= m
code := asTupleNewCode(underMode, #l,
[(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])
upNullTuple(op,l,tar) ==
-- handler for the empty tuple
defMode :=
tar and tar is [a,b] and (a in '(Stream Vector List)) and
not isPartialMode(b) => ['Tuple,b]
'(Tuple (None))
val := objNewWrap(asTupleNew(getVMType second defMode,0,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])
--% Handler for typeOf
uptypeOf form ==
form isnt [op, arg] => NIL
if VECP arg then transferPropsToNode(getUnname arg,arg)
if m := isType(arg) then
m := conceptualType m
else if not (m := getMode arg) then [m] := bottomUp arg
t := conceptualType m -- ??? shall we reveal more impl. details?
putValue(op, objNew(m,t))
putModeSet(op,[t])
--% Handler for where
upwhere t ==
-- upwhere does the puts in where into a local environment
t isnt [op,tree,clause] => NIL
-- since the "clause" might be a local macro, we now call mkAtree
-- on the "tree" part (it is not yet a vat)
not $genValue =>
compFailure [:bright '" where",
'"for compiled code is not yet implemented."]
$whereCacheList : local := nil
[env,:e] := upwhereClause(clause,$env,$e)
tree := upwhereMkAtree(tree,env,e)
if x := getAtree(op,'dollar) then
atom tree => throwKeyedMsg("S2IS0048",NIL)
putAtree(first tree,'dollar,x)
upwhereMain(tree,env,e)
val := getValue tree
putValue(op,val)
result := putModeSet(op,getModeSet tree)
wcl := [op for op in $whereCacheList]
for op in wcl repeat clearDependencies(op,'T)
result
upwhereClause(tree,env,e) ==
-- uses the variable bindings from env and e and returns an environment
-- of its own bindings
$env: local := copyHack env
$e: local := copyHack e
bottomUp tree
[$env,:$e]
upwhereMkAtree(tree,$env,$e) == mkAtree tree
upwhereMain(tree,$env,$e) ==
-- uses local copies of $env and $e while evaluating tree
bottomUp tree
copyHack(env) ==
-- makes a copy of an environment with the exception of pairs
-- (localModemap . something)
c:= CAAR env
d:= [fn p for p in c] where fn(p) ==
CONS(first p,[(q is ["localModemap",:.] => q; copy q) for q in rest p])
[[d]]
--% Case patterns
up%Match t ==
sorry '"case pattern"
--% importing domains
up%Import t ==
t isnt [.,:types] => nil
-- ??? shall we error in case types is nil?
for x in types repeat
$e := addDomain(devaluate objVal getValue x,$e)
setValueToVoid t
--% Macro handling
-- Well, in fact we never handle macros in the interpreter directly.
-- Rather, they are saved in the `macro processing phase' (phMacro)
-- to be used in future macro expansions, and the AST we get at this
-- point already went through the macro expansion massage. So, all we
-- have to do is to the rubber stamp.
up%Macro t ==
setValueToVoid t
up%MLambda t ==
setValueToVoid t
--% Sorry for unhandled input constructs
sorry kind ==
throwKeyedMsg("S2IP0006",[kind])
--% Export
up%Export t ==
sorry '"export declaration"
--% Inline
up%Inline t ==
sorry '"inline declaration"
--% Category
up%With t ==
sorry '"category definition"
--% Domain
up%Add t ==
sorry '"domain definition"
-- Creates the function names of the special function handlers and puts
-- them on the property list of the function name
for name in $specialOps repeat
functionName:=INTERNL('up,name)
MAKEPROP(name,'up,functionName)
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