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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 '"g-util"
)package "BOOT"
++ true if we are about to generate a function definition
$definingMap := false
++ List variables locat to the current function.
$localVars := []
++ declared mode of the current entity being processed.
$declaredMode := nil
++
$useIntegerSubdomain := true
--% Functions on interpreter objects
-- Interpreter objects used to be called triples because they had the
-- structure [value, type, environment]. For many years, the environment
-- was not used, so finally in January, 1990, the structure of objects
-- was changed to be (type . value). This was chosen because it was the
-- structure of objects of type Any. Sometimes the values are wrapped
-- (see the function isWrapped to see what this means physically).
-- Wrapped values are not actual values belonging to their types. An
-- unwrapped value must be evaluated to get an actual value. A wrapped
-- value must be unwrapped before being passed to a library function.
-- Typically, an unwrapped value in the interpreter consists of LISP
-- code, e.g., parts of a function that is being constructed.
-- RSS 1/14/90
-- These are the new structure functions.
objNew(val, mode) == CONS(mode,val) -- new names as of 10/14/93
objNewWrap(val, mode) == CONS(mode,wrap val)
objNewCode(val, mode) == ["CONS", MKQ mode,val ]
objSetVal(obj,val) == RPLACD(obj,val)
objSetMode(obj,mode) == RPLACA(obj,mode)
objVal obj == CDR obj
objValUnwrap obj == unwrap CDR obj
objMode obj == CAR obj
objEnv obj == $EmptyEnvironment
objCodeVal obj == CADDR obj
objCodeMode obj == CADR obj
--% Utility Functions Used Only by the Intepreter
wrap x ==
isWrapped x => x
["WRAPPED",:x]
isWrapped x == x is ['WRAPPED,:.] or NUMBERP x or FLOATP x or CVECP x
unwrap x ==
NUMBERP x or FLOATP x or CVECP x => x
x is ["WRAPPED",:y] => y
x
wrapped2Quote x ==
x is ["WRAPPED",:y] => MKQ y
x
quote2Wrapped x ==
x is ["QUOTE",y] => wrap y
x
removeQuote x ==
x is ["QUOTE",y] => y
x
-- addQuote x ==
-- NUMBERP x => x
-- ['QUOTE,x]
--% Library compiler structures needed by the interpreter
-- Tuples and Crosses
asTupleNew(size, listOfElts) == CONS(size, LIST2VEC listOfElts)
asTupleNew0(listOfElts) == CONS(#listOfElts, LIST2VEC listOfElts)
asTupleNewCode(size, listOfElts) == ["asTupleNew", size, ["LIST", :listOfElts]]
asTupleNewCode0(listForm) == ["asTupleNew0", listForm]
asTupleSize(at) == CAR at
asTupleAsVector(at) == CDR at
asTupleAsList(at) == VEC2LIST asTupleAsVector at
--% Basic Object Type Identification
++ The VAT class for literals values.
$immediateDataSymbol ==
"--immediateData--"
++ If x is a literal of the basic types (Integer String DoubleFloat) then
++ this function returns its type, and nil otherwise.
getBasicMode x == getBasicMode0(x,$useIntegerSubdomain)
++ Subroutine of getBasicMode.
getBasicMode0(x,useIntegerSubdomain) ==
x is nil => $EmptyMode
STRINGP x => $String
INTEGERP x =>
useIntegerSubdomain =>
x > 0 => $PositiveInteger
x = 0 => $NonNegativeInteger
$Integer
$Integer
FLOATP x => $DoubleFloat
(x='%noBranch) or (x='noValue) => $NoValueMode
nil
++ If x is a literal of the basic types then returns
++ an interpreter object denoting x, and nil otherwise.
getBasicObject x ==
INTEGERP x =>
t :=
not $useIntegerSubdomain => $Integer
x > 0 => $PositiveInteger
x = 0 => $NonNegativeInteger
$Integer
objNewWrap(x,t)
STRINGP x => objNewWrap(x,$String)
FLOATP x => objNewWrap(x,$DoubleFloat)
NIL
--%% Vectorized Attributed Trees
--% The interpreter translates parse forms into vats for analysis.
--% These contain a number of slots in each node for information.
--% The leaves are now all vectors, though the leaves for basic types
--% such as integers and strings used to just be the objects themselves.
--% The vectors for the leaves with such constants now have the value
--% of $immediateDataSymbol as their name. Their are undoubtably still
--% some functions that still check whether a leaf is a constant. Note
--% that if it is not a vector it is a subtree.
--% attributed tree nodes have the following form:
--% slot description
--% ---- -----------------------------------------------------
--% 0 operation name or literal
--% 1 declared mode of variable
--% 2 computed value of subtree from this node
--% 3 modeset: list of single computed mode of subtree
--% 4 prop list for extra things
++ create a leaf VAT node.
mkAtreeNode x ==
-- maker of attrib tree node
v := MAKE_-VEC 5
v.0 := x
v
++ remove mode, value, and misc. info from attrib tree
emptyAtree expr ==
VECP expr =>
$immediateDataSymbol = expr.0 => nil
expr.1:= NIL
expr.2:= NIL
expr.3:= NIL
-- kill proplist too?
atom expr => nil
for e in expr repeat emptyAtree e
++ returns true if x is a leaf VAT object.
isLeaf x ==
atom x --may be a number or a vector
++ returns the mode of the VAT node x.
getMode x ==
x is [op,:.] => getMode op
VECP x => x.1
m := getBasicMode x => m
keyedSystemError("S2II0001",[x])
++ sets the mode for the VAT node x to y.
putMode(x,y) ==
x is [op,:.] => putMode(op,y)
null VECP x => keyedSystemError("S2II0001",[x])
x.1 := y
++ returns an interpreter object that represents the value of node x.
++ Note that an interpreter object is a pair of mode and value.
getValue x ==
VECP x => x.2
atom x =>
t := getBasicObject x => t
keyedSystemError("S2II0001",[x])
getValue first x
++ sets the value of VAT node x to interpreter object y.
putValue(x,y) ==
x is [op,:.] => putValue(op,y)
null VECP x => keyedSystemError("S2II0001",[x])
x.2 := y
++ same as putValue(vec, val), except that vec is returned instead of val.
putValueValue(vec,val) ==
putValue(vec,val)
vec
++ Returns the node class of x, if possible; otherwise nil.
getUnnameIfCan x ==
VECP x => x.0
x is [op,:.] => getUnnameIfCan op
atom x => x
nil
++ Returns the node class of x; otherwise raise an error.
getUnname x ==
x is [op,:.] => getUnname op
getUnname1 x
++ Subroutine of getUnname.
getUnname1 x ==
VECP x => x.0
null atom x => keyedSystemError("S2II0001",[x])
x
++ returns the mode-set of VAT node x.
getModeSet x ==
x and PAIRP x => getModeSet first x
VECP x =>
y:= x.aModeSet =>
(y = [$EmptyMode]) and ((m := getMode x) is ['Mapping,:.]) =>
[m]
y
keyedSystemError("S2GE0016",['"getModeSet",'"no mode set"])
m:= getBasicMode x => [m]
not atom x => getModeSet first x
keyedSystemError("S2GE0016",['"getModeSet",
'"not an attributed tree"])
++ Sets the mode-set of VAT node x to y.
putModeSet(x,y) ==
x is [op,:.] => putModeSet(op,y)
not VECP x => keyedSystemError("S2II0001",[x])
x.3 := y
y
getModeOrFirstModeSetIfThere x ==
x is [op,:.] => getModeOrFirstModeSetIfThere op
VECP x =>
m := x.1 => m
val := x.2 => objMode val
y := x.aModeSet =>
(y = [$EmptyMode]) and ((m := getMode x) is ['Mapping,:.]) => m
first y
NIL
m := getBasicMode x => m
NIL
getModeSetUseSubdomain x ==
x and PAIRP x => getModeSetUseSubdomain first x
VECP(x) =>
-- don't play subdomain games with retracted args
getAtree(x,'retracted) => getModeSet x
y := x.aModeSet =>
(y = [$EmptyMode]) and ((m := getMode x) is ['Mapping,:.]) =>
[m]
val := getValue x
(x.0 = $immediateDataSymbol) and (y = [$Integer]) =>
val := objValUnwrap val
m := getBasicMode0(val,true)
x.2 := objNewWrap(val,m)
x.aModeSet := [m]
[m]
null val => y
isEqualOrSubDomain(objMode(val),$Integer) and
INTEGERP(f := objValUnwrap val) =>
[getBasicMode0(f,true)]
y
keyedSystemError("S2GE0016",
['"getModeSetUseSubomain",'"no mode set"])
m := getBasicMode0(x,true) => [m]
null atom x => getModeSetUseSubdomain first x
keyedSystemError("S2GE0016",
['"getModeSetUseSubomain",'"not an attributed tree"])
computedMode t ==
getModeSet t is [m] => m
keyedSystemError("S2GE0016",['"computedMode",'"non-singleton modeset"])
--% Other VAT properties
insertShortAlist(prop,val,al) ==
pair := QASSQ(prop,al) =>
RPLACD(pair,val)
al
[[prop,:val],:al]
putAtree(x,prop,val) ==
x is [op,:.] =>
-- only willing to add property if op is a vector
-- otherwise will be pushing to deeply into calling structure
if VECP op then putAtree(op,prop,val)
x
null VECP x => x -- just ignore it
n := QLASSQ(prop,'((mode . 1) (value . 2) (modeSet . 3)))
=> x.n := val
x.4 := insertShortAlist(prop,val,x.4)
x
getAtree(x,prop) ==
x is [op,:.] =>
-- only willing to get property if op is a vector
-- otherwise will be pushing to deeply into calling structure
VECP op => getAtree(op,prop)
NIL
null VECP x => NIL -- just ignore it
n:= QLASSQ(prop,'((mode . 1) (value . 2) (modeSet . 3)))
=> x.n
QLASSQ(prop,x.4)
putTarget(x, targ) ==
-- want to put nil modes perhaps to clear old target
if targ = $EmptyMode then targ := nil
putAtree(x,'target,targ)
getTarget(x) ==
getAtree(x,'target)
--% Source and position information
-- In the following, src is a string containing an original input line,
-- line is the line number of the string within the source file,
-- and col is the index within src of the start of the form represented
-- by x. x is a VAT.
++ returns source position information for VAT node x.
getSrcPos(x) ==
getAtree(x, 'srcAndPos)
++ sets the source location information for VAT node x.
putSrcPos(x, file, src, line, col) ==
putAtree(x, 'srcAndPos, srcPos_New(file, src, line, col))
srcPosNew(file, src, line, col) ==
LIST2VEC [file, src, line, col]
++ returns the name of source file for source location `sp'.
srcPosFile(sp) ==
if sp then sp.0 else nil
++ returns the input source string for source location `sp'.
srcPosSource(sp) ==
if sp then sp.1 else nil
++ returns the line number for source location `sp'.
srcPosLine(sp) ==
if sp then sp.2 else nil
++ returns the column number for source location `sp'.
srcPosColumn(sp) ==
if sp then sp.3 else nil
srcPosDisplay(sp) ==
null sp => nil
s := STRCONC('"_"", srcPosFile sp, '"_", line ",
STRINGIMAGE srcPosLine sp, '": ")
sayBrightly [s, srcPosSource sp]
col := srcPosColumn sp
dots :=
col = 0 => '""
fillerSpaces(col, '".")
sayBrightly [fillerSpaces(#s, '" "), dots, '"^"]
true
++ Returns the calling convention vector for an operation
++ represented by the VAT `t'.
getFlagArgsPos t ==
VECP t => getAtree(t, 'flagArgsPos)
atom t => keyedSystemError("S2II0001",[t])
getFlagArgsPos car t
--% Transfer of VAT properties.
transferPropsToNode(x,t) ==
propList := getProplist(x,$env)
QLASSQ('Led,propList) or QLASSQ('Nud,propList) => nil
node :=
VECP t => t
first t
for prop in '(mode localModemap value name generatedCode)
repeat transfer(x,node,prop)
where
transfer(x,node,prop) ==
u := get(x,prop,$env) => putAtree(node,prop,u)
(not (x in $localVars)) and (u := get(x,prop,$e)) =>
putAtree(node,prop,u)
if not getMode(t) and (am := get(x,'automode,$env)) then
putModeSet(t,[am])
putMode(t,am)
t
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