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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_-object
import ptrees
namespace BOOT
$useParserSrcPos := NIL
$transferParserSrcPos := NIL
-- Making Trees
mkAtree x ==
-- maker of attrib tree from parser form
mkAtree1 mkAtreeExpandMacros x
mkAtreeWithSrcPos(form, posnForm) ==
posnForm and $useParserSrcPos => pf2Atree(posnForm)
transferSrcPosInfo(posnForm, mkAtree form)
mkAtree1WithSrcPos(form, posnForm) ==
transferSrcPosInfo(posnForm, mkAtree1 form)
mkAtreeNodeWithSrcPos(form, posnForm) ==
transferSrcPosInfo(posnForm, mkAtreeNode form)
transferSrcPosInfo(pf, atree) ==
not (pf and $transferParserSrcPos) => atree
pos := pfPosOrNopos(pf)
pfNoPosition?(pos) => atree
-- following is a hack because parser code for getting filename
-- seems wrong.
fn := lnPlaceOfOrigin poGetLineObject(pos)
if null fn or fn = '"strings" then fn := '"console"
putSrcPos(atree, fn, pfSourceText(pf), pfLinePosn(pos), pfCharPosn(pos))
atree
mkAtreeExpandMacros x ==
-- handle macro expansion. if the macros have args we require that
-- we match the correct number of args
if x isnt ["MDEF",:.] and x isnt ["DEF",["macro",:.],:.] then
atom x and (m := isInterpMacro x) =>
[args,:body] := m
args => "doNothing"
x := body
x is [op,:argl] =>
op = "QUOTE" => "doNothing"
op = "where" and argl is [before,after] =>
-- in a where clause, what follows "where" (the "after" parm
-- above) might be a local macro, so do not expand the "before"
-- part yet
x := [op,before,mkAtreeExpandMacros after]
argl := [mkAtreeExpandMacros a for a in argl]
(m := isInterpMacro op) =>
[args,:body] := m
#args = #argl =>
sl := [[a,:s] for a in args for s in argl]
x := SUBLISNQ(sl,body)
null args => x := [body,:argl]
x := [op,:argl]
x := [mkAtreeExpandMacros op,:argl]
x
mkAtree1 x ==
-- first special handler for making attrib tree
null x => throwKeyedMsg("S2IP0005",['"NIL"])
vector? x => x
atom x =>
x in '(%noBranch %noMapVal) => x
x in '(nil true false) => mkAtree2([x],x,NIL)
x = '_/throwAway =>
-- don't want to actually compute this
tree := mkAtree1 '(void)
putValue(tree,objNewWrap(voidValue(),$Void))
putModeSet(tree,[$Void])
tree
getBasicMode x =>
v := mkAtreeNode $immediateDataSymbol
putValue(v,getBasicObject x)
v
IDENTP x => mkAtreeNode x
keyedSystemError("S2II0002",[x])
x is [op,:argl] => mkAtree2(x,op,argl)
systemErrorHere ["mkAtree1",x]
-- mkAtree2 and mkAtree3 were created because mkAtree1 got so big
mkAtree2(x,op,argl) ==
nargl := #argl
(op= "-") and (nargl = 1) and (integer? first argl) =>
mkAtree1(MINUS first argl)
op=":" and argl is [y,z] => [mkAtreeNode "Declare",:argl]
op="COLLECT" => [mkAtreeNode op,:transformCollect argl]
op= "break" =>
argl is [.,val] =>
if val = '$NoValue then val := '(void)
[mkAtreeNode op,mkAtree1 val]
[mkAtreeNode op,mkAtree1 '(void)]
op= "return" =>
argl is [val] =>
if val = '$NoValue then val := '(void)
[mkAtreeNode op,mkAtree1 val]
[mkAtreeNode op,mkAtree1 '(void)]
op="exit" => mkAtree1 second argl
op = "QUOTE" => [mkAtreeNode op,:argl]
op="SEGMENT" =>
argl is [a] => [mkAtreeNode op, mkAtree1 a]
z :=
null argl.1 => nil
mkAtree1 argl.1
[mkAtreeNode op, mkAtree1 argl.0,z]
op in '(pretend is isnt) =>
[mkAtreeNode op,mkAtree1 first argl,:rest argl]
op = "::" =>
[mkAtreeNode "COERCE",mkAtree1 first argl,second argl]
x is ["@", expr, type] =>
t := evaluateType unabbrev type
t = $DoubleFloat and expr is [['_$elt, =$Float, 'float], :args] =>
mkAtree1 [['_$elt, $DoubleFloat, 'float], :args]
t = $DoubleFloat and integer? expr =>
v := mkAtreeNode $immediateDataSymbol
putValue(v,getBasicObject float expr)
v
t = $Float and integer? expr =>
mkAtree1 ["::", expr, t]
typeIsASmallInteger(t) and integer? expr =>
mkAtree1 ["::", expr, t]
[mkAtreeNode 'TARGET,mkAtree1 expr, type]
(op="case") and (nargl = 2) =>
[mkAtreeNode "case",mkAtree1 first argl,unabbrev second argl]
op="REPEAT" => [mkAtreeNode op,:transformREPEAT argl]
op="%LET" and argl is [['construct,:.],rhs] =>
[mkAtreeNode "%LET",first argl,mkAtree1 rhs]
op="%LET" and argl is [[":",a,.],rhs] =>
mkAtree1 ["SEQ",first argl,["%LET",a,rhs]]
op is ['_$elt,D,op1] =>
op1 is "=" =>
a' := [mkAtreeNode '_=,:[mkAtree1 arg for arg in argl]]
[mkAtreeNode "Dollar",D,a']
[mkAtreeNode "Dollar",D,mkAtree1 [op1,:argl]]
op='_$elt =>
argl is [D,a] =>
integer? a =>
a = 0 => mkAtree1 [['_$elt,D,'Zero]]
a = 1 => mkAtree1 [['_$elt,D,'One]]
t := evaluateType unabbrev [D]
typeIsASmallInteger(t) and SINTP a =>
v := mkAtreeNode $immediateDataSymbol
putValue(v,objNewWrap(a, t))
v
mkAtree1 ["*",a,[['_$elt,D,'One]]]
[mkAtreeNode "Dollar",D,mkAtree1 a]
keyedSystemError("S2II0003",['"$",argl,
'"not qualifying an operator"])
mkAtree3(x,op,argl)
mkAtree3(x,op,argl) ==
op="REDUCE" and argl is [op1,axis,body] =>
[mkAtreeNode op,axis,mkAtree1 op1,mkAtree1 body]
op="has" => [mkAtreeNode op, :argl]
op="|" => [mkAtreeNode "AlgExtension",:[mkAtree1 arg for arg in argl]]
op="=" => [mkAtreeNode "equation",:[mkAtree1 arg for arg in argl]]
op="not" and argl is [["=",lhs,rhs]] =>
[mkAtreeNode "not",[mkAtreeNode "=",mkAtree1 lhs,mkAtree1 rhs]]
op="in" and argl is [var ,["SEGMENT",lb,ul]] =>
upTest:=
null ul => NIL
mkLessOrEqual(var,ul)
lowTest:=mkLessOrEqual(lb,var)
z :=
ul => ['and,lowTest,upTest]
lowTest
mkAtree1 z
x is ["IF",p,"%noBranch",a] => mkAtree1 ["IF",["not",p],a,"%noBranch"]
x is ["RULEDEF",:.] => [mkAtreeNode "RULEDEF",:rest x]
x is ["MDEF",sym,junk1,junk2,val] =>
-- new macros look like macro f == or macro f(x) ===
-- so transform into that format
mkAtree1 ["DEF",["macro",sym],junk1,junk2,val]
x is ["+->",funargs,funbody] =>
if funbody is [":",body,type] then
types := [type]
funbody := body
else types := [NIL]
v := collectDefTypesAndPreds funargs
types := [:types,:v.1]
[mkAtreeNode "ADEF",[v.0,types,[NIL for a in types],funbody],
if v.2 then v.2 else true, false]
x is ['ADEF,arg,:r] =>
r := mkAtreeValueOf r
v :=
null arg => VECTOR(NIL,NIL,NIL)
cons? arg and rest arg and first arg ~= "|" =>
collectDefTypesAndPreds ["tuple",:arg]
null rest arg => collectDefTypesAndPreds first arg
collectDefTypesAndPreds arg
[types,:r'] := r
at := [fn(x,y) for x in rest types for y in v.1]
r := [[first types,:at],:r']
[mkAtreeNode "ADEF",[v.0,:r],if v.2 then v.2 else true,false]
x is ["where",before,after] =>
[mkAtreeNode "where",before,mkAtree1 after]
x is ["DEF",["macro",form],.,.,body] =>
[mkAtreeNode "MDEF",form,body]
x is ["DEF",a,:r] =>
r := mkAtreeValueOf r
a is [op,:arg] =>
v :=
null arg => VECTOR(NIL,NIL,NIL)
cons? arg and rest arg and first arg ~= "|" =>
collectDefTypesAndPreds ["tuple",:arg]
null rest arg => collectDefTypesAndPreds first arg
collectDefTypesAndPreds arg
[types,:r'] := r
-- see case for ADEF above for defn of fn
at := [fn(x,y) for x in rest types for y in v.1]
r := [[first types,:at],:r']
[mkAtreeNode 'DEF,[[op,:v.0],:r],if v.2 then v.2 else true,false]
[mkAtreeNode 'DEF,[a,:r],true,false]
op = "%Match" => [mkAtreeNode op, mkAtree1 first argl, second argl]
op="[||]" => [mkAtreeNode op, :argl]
op in '(%Inline %With %Add %Export) => [mkAtreeNode op,:argl]
--x is ['when,y,pred] =>
-- y isnt ['DEF,a,:r] =>
-- keyedSystemError("S2II0003",['"when",y,'"improper argument form"])
-- a is [op,p1,:pr] =>
-- null pr => mkAtree1 ['DEF,[op,["|",p1,pred]],:r]
-- mkAtree1 ['DEF,[op,["|",["tuple",p1,:pr],pred]],:r]
-- [mkAtreeNode 'DEF, rest y,pred,false]
--x is ['otherwise,u] =>
-- throwMessage '" otherwise is no longer supported."
z :=
getBasicMode op =>
v := mkAtreeNode $immediateDataSymbol
putValue(v,getBasicObject op)
v
atom op =>
t := mkAtreeNode op
putAtree(t, 'flagArgsPos, flagArguments(op,#argl))
t
mkAtree1 op
-- this is a general form handled by modemap selection. Be
-- careful not to evaluate arguments that are not meant to.
flagArgPos := getFlagArgsPos z
[z,:[buildTreeForOperand for y in argl for i in 0..]] where
buildTreeForOperand() ==
flagArgPos and flagArgPos.i > 0 =>
-- Match old parser normal form.
y' := resolveNiladicConstructors y
a := mkAtreeNode $immediateDataSymbol
m := quasiquote y'
putMode(a, m)
putValue(a, objNewWrap(MKQ y',m))
putModeSet(a, [m])
a
mkAtree1 y
where
fn(a,b) ==
a and b =>
if a = b then a
else throwMessage '" double declaration of parameter"
a or b
++ Check if op accepts flag arguments. If so, returns a vector whose
++ positive entry indicates that modemaps for `op' takes flag arguments
++ in that position.
flagArguments(op, nargs) ==
v := GETZEROVEC nargs
sigs := [signatureFromModemap m for m in getModemapsFromDatabase(op, nargs)]
checkCallingConvention(sigs, nargs)
++ Extract the signature of modemap `m'.
signatureFromModemap m ==
[sig,pred,:.] := m
pred = true => rest sig
pred.op in '(AND %and) =>
sl := [[a,:b] for [.,a,b] in rest pred]
rest SUBLIS(sl,sig)
collectDefTypesAndPreds args ==
-- given an arglist to a DEF-like form, this function returns
-- a vector of three things:
-- slot 0: just the variables
-- slot 1: the type declarations on the variables
-- slot 2: a predicate for all arguments
pred := types := vars := NIL
junk :=
IDENTP args =>
types := [NIL]
vars := [args]
args is [":",var,type] =>
types := [type]
var is ["|",var',p] =>
vars := [var']
pred := addPred(pred,p)
vars := [var]
args is ["|",var,p] =>
pred := addPred(pred,p)
var is [":",var',type] =>
types := [type]
vars := [var']
var is ["tuple",:.] or var is ["|",:.] =>
v := collectDefTypesAndPreds var
vars := [:vars,:v.0]
types := [:types,:v.1]
pred := addPred(pred,v.2)
vars := [var]
types := [NIL]
args is ["tuple",:args'] =>
for a in args' repeat
v := collectDefTypesAndPreds a
vars := [:vars,first v.0]
types := [:types,first v.1]
pred := addPred(pred,v.2)
types := [NIL]
vars := [args]
VECTOR(vars,types,pred)
where
addPred(old,new) ==
null new => old
null old => new
['and,old,new]
mkAtreeValueOf l ==
-- scans for ['valueOf,atom]
not CONTAINED("valueOf",l) => l
mkAtreeValueOf1 l
mkAtreeValueOf1 l ==
null l or atom l or null rest l => l
l is ["valueOf",u] and IDENTP u =>
v := mkAtreeNode $immediateDataSymbol
putValue(v,get(u,"value",$InteractiveFrame) or
objNewWrap(u,['Variable,u]))
v
[mkAtreeValueOf1 x for x in l]
mkLessOrEqual(lhs,rhs) == ["not",["<",rhs,lhs]]
atree2EvaluatedTree x == atree2Tree1(x,true)
atree2Tree1(x,evalIfTrue) ==
(triple := getValue x) and objMode(triple) ~= $EmptyMode =>
coerceOrCroak(triple,$OutputForm,$mapName)
isLeaf x =>
vector? x => x.0
x
[atree2Tree1(y,evalIfTrue) for y in x]
--% Environment Utilities
-- getValueFromEnvironment(x,mode) ==
-- $failure ~= (v := getValueFromSpecificEnvironment(x,mode,$env)) => v
-- $failure ~= (v := getValueFromSpecificEnvironment(x,mode,$e)) => v
-- throwKeyedMsg("S2IE0001",[x])
getValueFromEnvironment(x,mode) ==
$failure ~= (v := getValueFromSpecificEnvironment(x,mode,$env)) => v
$failure ~= (v := getValueFromSpecificEnvironment(x,mode,$e)) => v
null(v := coerceInt(objNew(x, ['Variable, x]), mode)) =>
throwKeyedMsg("S2IE0001",[x])
objValUnwrap v
getValueFromSpecificEnvironment(id,mode,e) ==
cons? e =>
u := get(id,'value,e) =>
objMode(u) = $EmptyMode =>
systemErrorHere ["getValueFromSpecificEnvironment",id]
v := objValUnwrap u
mode isnt ['Mapping,:mapSig] => v
v isnt ["%Map",:.] => v
v' := coerceInt(u,mode)
null v' => throwKeyedMsg("S2IC0002",[objMode u,mode])
objValUnwrap v'
m := get(id,'mode,e) =>
-- See if we can make it into declared mode from symbolic form
-- For example, (x : P[x] I; x + 1)
if isPartialMode(m) then m' := resolveTM(['Variable,id],m)
else m' := m
m' and
(u := coerceInteractive(objNewWrap(id,['Variable,id]),m')) =>
objValUnwrap u
throwKeyedMsg("S2IE0002",[id,m])
$failure
$failure
getFlag x == get("--flags--",x,$e)
putFlag(flag,value) ==
$e := put ("--flags--", flag, value, $e)
getI(x,prop) == get(x,prop,$InteractiveFrame)
putI(x,prop,val) == ($InteractiveFrame := put(x,prop,val,$InteractiveFrame))
getIProplist x == getProplist(x,$InteractiveFrame)
removeBindingI x ==
first($InteractiveFrame).first := deleteAssocWOC(x,CAAR $InteractiveFrame)
rempropI(x,prop) ==
id:=
atom x => x
first x
getI(id,prop) =>
recordNewValue(id,prop,NIL)
recordOldValue(id,prop,getI(id,prop))
$InteractiveFrame:= remprop(id,prop,$InteractiveFrame)
remprop(x,prop,e) ==
u:= assoc(prop,pl:= getProplist(x,e)) =>
e:= addBinding(x,DELASC(first u,pl),e)
e
e
fastSearchCurrentEnv(x,currentEnv) ==
u:= QLASSQ(x,first currentEnv) => u
while (currentEnv:= rest currentEnv) repeat
u:= QLASSQ(x,first currentEnv) => u
transformCollect [:itrl,body] ==
-- syntactic transformation for COLLECT form, called from mkAtree1
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 ["UNTIL",:.] => nil
throwKeyedMsg("S2IS0061",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 ["UNTIL",b] =>
[["UNTIL",mkAtree1 b]]
it is ["|",pred] => nil
[:iterList,bodyTree]
--%
++ Make a VAT for the symbol `x' and collect all known information
++ about `x' in the current environment into the new VAT.
++ Note: This routine is used in the algebra interface to the interpreter.
mkAtreeForToken: %Symbol -> %Shell
mkAtreeForToken x ==
t := mkAtreeNode x
transferPropsToNode(x,t)
|