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|
-- Copyright (C) 2011, 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.
--%
--% The purpose of this module is to implement the Lisp backend
--% of the OpenAxiom platform. This is achieved by necessary
--% collection runtime datatypes and Common Lisp code generation
--% routines.
--%
import sys_-macros
namespace BOOT
module lisp_-backend where
expandToVMForm: %Thing -> %Thing
eval: %Thing -> %Thing
--%
--% Iteration control structures
--%
--% Code generation for an iterator produces a sequence of
--% length 5, whose components have the following meanings:
--% 0. list of loop-wide variables and their initializers
--% 1. list of body-wide variables and their initializers
--% 2. update code for next iteration
--% 3. predicate guarding loop body execution
--% 4. loop termination predicate
++ Generate code that sequentially visits each component of a list.
expandIN(x,l,early?) ==
g := gensym() -- rest of the list yet to be visited
early? => -- give the loop variable a wider scope.
[[[g,middleEndExpand l],[x,'NIL]],
nil,[['SETQ,g,['CDR,g]]],
nil,[['ATOM,g],['PROGN,['SETQ,x,['CAR,g]],'NIL]]]
[[[g,middleEndExpand l]],
[[x,['CAR,g]]],[['SETQ,g,['CDR,g]]],
nil,[['ATOM,g]]]
expandON(x,l) ==
[[[x,middleEndExpand l]],nil,[["SETQ",x,["CDR",x]]],nil,[["ATOM",x]]]
++ Generate code that traverses an interval with lower bound 'lo',
++ arithmetic progression `step, and possible upper bound `final'.
expandSTEP(id,lo,step,final)==
lo := middleEndExpand lo
step := middleEndExpand step
final := middleEndExpand final
loopvar := [[id,lo]]
inc :=
atomic? step => step
g1 := gensym()
loopvar := [:loopvar,[g1,step]]
g1
final :=
atom final => final
final is [hi] and atomic? hi => hi
g2 := gensym()
loopvar := [:loopvar,[g2,:final]]
g2
ex :=
final = nil => nil
integer? inc =>
pred :=
MINUSP inc => "<"
">"
[[pred,id,final]]
[['COND,[['MINUSP,inc],
["<",id,final]],['T,[">",id,final]]]]
suc := [["SETQ",id,["+",id,inc]]]
[loopvar,nil,suc,nil,ex]
++ Generate code for iterators that filter out execution state
++ not satisfying predicate `p'.
expandSUCHTHAT p ==
[nil,nil,nil,[middleEndExpand p],nil]
++ Generate code for iterators that stop loop iteration when the
++ state fails predicate `p'.
expandWHILE p ==
[nil,nil,nil,nil,[["NOT",middleEndExpand p]]]
expandUNTIL p ==
g := gensym()
[[[g,false]],nil,[["SETQ",g,middleEndExpand p]],nil,[g]]
expandInit(var,val) ==
[[[var,middleEndExpand val]],nil,nil,nil,nil]
expandIterators iters ==
-- Exit predicates may reference iterator variables. In that case,
-- the scope the variables must cover the generated loop body. The
-- following is much more coarse approximation than we may want,
-- but it will do. For now.
early? := or/[ it.op in '(WHILE UNTIL) for it in iters]
[toLisp(it,early?) or leave "failed" for it in iters] where
toLisp(it,early?) ==
it is ["STEP",var,lo,inc,:hi] => expandSTEP(var,lo,inc,hi)
it is ["IN",var,seq] => expandIN(var,seq,early?)
it is ["ON",var,seq] => expandON(var,seq)
it is ["WHILE",pred] => expandWHILE pred
it is [op,pred] and op in '(SUCHTHAT _|) => expandSUCHTHAT pred
it is ["UNTIL",pred] => expandUNTIL pred
it is ["%init",var,val] => expandInit(var,val)
nil
expandLoop ['%loop,:iters,body,ret] ==
itersCode := expandIterators iters
itersCode = "failed" => systemErrorHere ["expandLoop",iters]
body := middleEndExpand body
itersCode := "coagulate"/itersCode
where
coagulate(it1,it2) == [append(it1.k,it2.k) for k in 0..4]
[loopInits,bodyInits,cont,filters,exits] := itersCode
-- Guard the execution of the body by the filters.
if filters ~= nil then
body := mkpf([:filters,body],"AND")
-- If there is any body-wide initialization, now is the time.
if bodyInits ~= nil then
body := ["LET",bodyInits,body]
exits := ["COND",
[mkpf(exits,"OR"),["RETURN",expandToVMForm ret]],
[true,body]]
body := ["LOOP",exits,:cont]
-- Finally, set up loop-wide initializations.
loopInits = nil => body
["LET",loopInits,body]
++ Generate code for list comprehension.
expandCollect ['%collect,:iters,body] ==
val := gensym() -- result of the list comprehension
-- Transform the body to build the list as we go.
body := ["SETQ",val,["CONS",middleEndExpand body,val]]
-- Initialize the variable holding the result; expand as
-- if ordinary loop. But don't forget we built the result
-- in reverse order.
expandLoop ['%loop,:iters,["%init",val,nil],body,["NREVERSE",val]]
expandList(x is ['%list,:args]) ==
args := [expandToVMForm arg for arg in args]
args = nil => nil
args' := [simpleValue? arg or leave 'failed for arg in args]
where simpleValue? arg ==
integer? arg or string? arg => arg
arg is ['QUOTE,form] => form
nil
args' = 'failed => ['LIST,:args]
quoteForm args'
expandReturn(x is ['%return,.,y]) ==
$FUNNAME = nil => systemErrorHere ['expandReturn,x]
['RETURN_-FROM,$FUNNAME,expandToVMForm y]
-- Pointer operations
expandPeq ['%peq,x,y] ==
x = '%nil => ['NULL,expandToVMForm y]
y = '%nil => ['NULL,expandToVMForm x]
['EQ,expandToVMForm x, expandToVMForm y]
expandBefore? ['%before?,x,y] ==
['GGREATERP,expandToVMForm y,expandToVMForm x]
-- Byte operations
expandBcompl ['%bcompl,x] ==
integer? x => 255 - x
['_+,256,['LOGNOT,expandToVMForm x]]
-- Character operations
expandCcst ['%ccst,s] ==
-- FIXME: this expander should return forms, instead of character constants
not string? s => error "operand is not a string constant"
stringToChar s
++ string-to-character conversion.
expandS2c ['%s2c, x] ==
string? x => expandCcst ['%ccst, x]
['stringToChar, x]
-- Integer operations
expandIneg ['%ineg,x] ==
x := expandToVMForm x
integer? x => -x
['_-,x]
expandIdivide ['%idivide,x,y] ==
['MULTIPLE_-VALUE_-CALL,['FUNCTION,'CONS],
['TRUNCATE,expandToVMForm x,expandToVMForm y]]
expandIeq ['%ieq,a,b] ==
a := expandToVMForm a
integer? a and a = 0 => ['ZEROP,expandToVMForm b]
b := expandToVMForm b
integer? b and b = 0 => ['ZEROP,a]
['EQL,a,b]
expandIlt ['%ilt,x,y] ==
integer? x and x = 0 =>
integer? y => y > 0
['PLUSP,expandToVMForm y]
integer? y and y = 0 =>
integer? x => x < 0
['MINUSP,expandToVMForm x]
['_<,expandToVMForm x,expandToVMForm y]
expandIgt ['%igt,x,y] ==
expandIlt ['%ilt,y,x]
-- Floating point support
expandFbase ['%fbase] ==
FLOAT_-RADIX $DoubleFloatMaximum
expandFprec ['%fprec] ==
FLOAT_-DIGITS $DoubleFloatMaximum
expandFminval ['%fminval] ==
'$DoubleFloatMinimum
expandFmaxval ['%fmaxval] ==
'$DoubleFloatMaximum
expandI2f ['%i2f,x] ==
x := expandToVMForm x
integer? x and (x = 0 or x = 1) => FLOAT(x,$DoubleFloatMaximum)
['FLOAT,x,'$DoubleFloatMaximum]
expandFneg ['%fneg,x] ==
['_-,expandToVMForm x]
expandFeq ['%feq,a,b] ==
a is ['%i2f,0] => ['ZEROP,expandToVMForm b]
b is ['%i2f,0] => ['ZEROP,expandToVMForm a]
['_=,expandToVMForm a,expandToVMForm b]
expandFlt ['%flt,x,y] ==
x is ['%i2f,0] => ['PLUSP,expandToVMForm y]
y is ['%i2f,0] => ['MINUSP,expandToVMForm x]
['_<,expandToVMForm x,expandToVMForm y]
expandFgt ['%fgt,x,y] ==
expandFlt ['%flt,y,x]
expandFcstpi ['%fcstpi] ==
['COERCE,'PI,quoteForm '%DoubleFloat]
expandFsqrt ['%fsqrt,x] ==
['C_-TO_-R,['SQRT,expandToVMForm x]]
expandFpowf ['%fpowf,x,y] ==
['C_-TO_-R,['EXPT,expandToVMForm x,expandToVMForm y]]
expandFlog ['%flog,x] ==
['C_-TO_-R,['LOG,expandToVMForm x]]
expandFlog2 ['%flog2,x] ==
['C_-TO_-R,['LOG,expandToVMForm x,2]]
expandFlog10 ['%flog10,x] ==
['C_-TO_-R,['LOG,expandToVMForm x,10]]
expandFasin ['%fasin,x] ==
['C_-TO_-R,['ASIN,expandToVMForm x]]
expandFacos ['%facos,x] ==
['C_-TO_-R,['ACOS,expandToVMForm x]]
expandFacosh ['%facosh,x] ==
['C_-TO_-R,['ACOSH,expandToVMForm x]]
expandFatanh ['%fatanh,x] ==
['C_-TO_-R,['ATANH,expandToVMForm x]]
expandFacoth ['%facoth,x] ==
['C_-TO_-R,['ACOTH,expandToVMForm x]]
-- String operations
++ string equality comparison
expandStreq ['%streq,x,y] ==
expandToVMForm ['%not,['%peq,['STRING_=,x,y],'%nil]]
++ string lexicographic comparison
expandStrlt ['%strlt,x,y] ==
expandToVMForm ['%not,['%peq,['STRING_<,x,y],'%nil]]
++ deposit a character `z' at slot number `y' in string object `x'.
expandStrstc ['%strstc,x,y,z] ==
expandToVMForm ['%store,['%schar,x,y],z]
-- bit vector operations
expandBitvecnot ['%bitvecnot,x] ==
['BIT_-NOT,expandToVMForm x]
expandBitvecand ['%bitvecand,x,y] ==
['BIT_-AND,expandToVMForm x,expandToVMForm y]
expandBitvecnand ['%bitvecnand,x,y] ==
['BIT_-NAND,expandToVMForm x,expandToVMForm y]
expandBitvecor ['%bitvecor,x,y] ==
['BIT_-IOR,expandToVMForm x,expandToVMForm y]
expandBitvecnor ['%bitvecnor,x,y] ==
['BIT_-NOR,expandToVMForm x,expandToVMForm y]
expandBitvecxor ['%bitvecxor,x,y] ==
['BIT_-XOR,expandToVMForm x,expandToVMForm y]
expandBitveclength ['%bitveclength,x] ==
['LENGTH,expandToVMForm x]
expandBitveccopy ['%bitveccopy,x] ==
['COPY_-SEQ,expandToVMForm x]
expandBitvecconc ['%bitvecconc,x,y] ==
['CONCATENATE, quoteForm '%BitVector,expandToVMForm x,expandToVMForm y]
expandBitvecref ['%bitvecref,x,y] ==
['SBIT,expandToVMForm x,expandToVMForm y]
expandBitveceq ['%bitveceq,x,y] ==
['EQUAL,expandToVMForm x,expandToVMForm y]
expandBitveclt ['%bitveclt,x,y] ==
['BVEC_-GREATER,expandToVMForm y,expandToVMForm x]
expandBitvector ['%bitvector,x,y] ==
['MAKE_-ARRAY,['LIST,expandToVMForm x],
KEYWORD::ELEMENT_-TYPE,quoteForm '%Bit,
KEYWORD::INITIAL_-ELEMENT,expandToVMForm y]
--% complex number conversions
--% An OpenAxiom complex number is a pair (real and imaginary parts.)
-- convert an OpenAxiom complex number to a Lisp complex number
expandVal2z ['%val2z,x] ==
cons? x =>
g := gensym()
expandToVMForm ['%bind,[[g,x]],['%zlit,['%head,g],['%tail,g]]]
expandToVMForm ['%zlit,['%head,x],['%tail,x]]
-- convert a Lisp complex number to an OpenAxiom complex number
expandZ2val ['%z2val,x] ==
cons? x =>
g := gensym()
expandToVMForm ['%bind,[[g,x]],['%pair,['%zreal,g],['%zimag,g]]]
expandToVMForm ['%pair,['%zreal,x],['%zimag,x]]
-- Local variable bindings
expandBind ['%bind,inits,:body] ==
body := expandToVMForm body
inits := [[first x,expandToVMForm second x] for x in inits]
-- FIXME: we should consider turning LET* into LET or direct inlining.
op :=
or/[CONTAINED(v,x) for [[v,.],:x] in tails inits] => 'LET_*
'LET
[op,inits,:body]
-- Memory load/store
expandDynval ["%dynval",:args] ==
["SYMBOL-VALUE",:expandToVMForm args]
expandStore ["%store",place,value] ==
value := expandToVMForm value
place is ['%head,x] => ['RPLACA,expandToVMForm x,value]
place is ['%tail,x] => ['RPLACD,expandToVMForm x,value]
place := expandToVMForm place
cons? place => ["SETF",place,value]
["SETQ",place,value]
-- non-local control transfer
$OpenAxiomCatchTag == KEYWORD::OpenAxiomCatchPoint
expandThrow ['%throw,m,x] ==
['THROW,$OpenAxiomCatchTag,
['CONS,$OpenAxiomCatchTag,
['CONS,expandToVMForm m,expandToVMForm x]]]
++ Subroutine of expandTry. Generate code for domain matching
++ of object `obj' with domain `dom'.
domainMatchCode(dom,obj) ==
-- FIXME: Instead of domain equality, we should also consider
-- FIXME: cases of sub-domains, or domain schemes with constraints.
['domainEqual,dom,['%head,obj]]
expandTry ['%try,expr,handlers,cleanup] ==
g := gensym() -- hold the exception object
ys := [[domainMatchCode(mode,['%tail,g]),
['%bind,[[var,['%tail,['%tail,g]]]],stmt]]
for [.,var,mode,stmt] in handlers]
handlerBody :=
ys = nil => g
ys := [:ys,['%otherwise,['THROW,$OpenAxiomCatchTag,g]]]
['%when,
[['%and,['%pair?,g],
['%peq,['%head,g],$OpenAxiomCatchTag]], ['%when,:ys]],
['%otherwise,g]]
tryBlock := expandBind
['%bind,[[g,['CATCH,$OpenAxiomCatchTag,expr]]],handlerBody]
cleanup = nil => tryBlock
['UNWIND_-PROTECT,tryBlock,:expandToVMForm rest cleanup]
++ Opcodes with direct mapping to target operations.
for x in [
-- Boolean constants
-- ['%false, :'NIL],
['%true, :'T],
-- unary Boolean operations
['%not, :'NOT],
['%2bit, :'TRUTH_-TO_-BIT],
['%2bool, :'BIT_-TO_-TRUTH],
-- binary Boolean operations
['%and, :'AND],
['%or, :'OR],
-- character operations
['%ceq, :'CHAR_=],
['%clt, :'CHAR_<],
['%cle, :'CHAR_<_=],
['%cgt, :'CHAR_>],
['%cge, :'CHAR_>_=],
['%cup, :'CHAR_-UPCASE],
['%cdown, :'CHAR_-DOWNCASE],
['%c2i, :'CHAR_-CODE],
['%i2c, :'CODE_-CHAR],
['%c2s, :'STRING],
-- byte operations
['%beq, :'byteEqual],
['%blt, :'byteLessThan],
-- unary integer operations.
['%iabs, :'ABS],
['%ieven?, :'EVENP],
['%integer?,:'INTEGERP],
['%iodd?, :'ODDP],
['%ismall?, :'SMINTP],
['%i2s, :'WRITE_-TO_-STRING],
['%ilength, :'INTEGER_-LENGTH],
['%ibit, :'INTEGER_-BIT],
-- binary integer operations.
['%iadd, :"+"],
['%igcd, :'GCD],
['%ige, :">="],
['%iinc, :"1+"],
['%idec, :"1-"],
['%ilcm, :'LCM],
['%ile, :"<="],
['%imax, :'MAX],
['%imin, :'MIN],
['%imul, :"*"],
['%imulf, :"*"], -- integer * float
['%irem, :'REM],
['%iquo, :'TRUNCATE],
['%ipow, :'EXPT],
['%isub, :"-"],
['%bitand, :'LOGAND],
['%bitior, :'LOGIOR],
['%bitxor, :'LOGXOR],
['%bitnot, :'LOGNOT],
-- unary float operations.
['%fabs, :'ABS],
['%float?,:'FLOATP],
['%ftrunc,:'TRUNCATE],
-- binary float operations.
['%fadd, :"+"],
['%fdiv, :"/"],
['%fdivi, :"/"], -- float / integer
['%fge, :">="],
['%fle, :"<="],
['%fmax, :'MAX],
['%fmin, :'MIN],
['%fmul, :"*"],
['%fpowi, :'EXPT],
['%fsub, :"-"],
['%fmanexp, :'MANEXP], -- (mantissa, exponent) pair.
['%fexp, :'EXP],
['%fsin, :'SIN],
['%fcos, :'COS],
['%ftan, :'TAN],
['%fcot, :'COT],
['%fatan, :'ATAN],
['%facot, :'ACOT],
['%fsinh, :'SINH],
['%fcosh, :'COSH],
['%ftanh, :'TANH],
['%fasinh, :'ASINH],
-- complex number operations
['%zlit, :'COMPLEX],
['%zreal, :'REALPART],
['%zimag, :'IMAGPART],
['%zexp, :'EXP],
['%zlog, :'LOG],
['%zsin, :'SIN],
['%zcos, :'COS],
['%ztan, :'TAN],
['%zasin, :'ASIN],
['%zacos, :'ACOS],
['%zatan, :'ATAN],
['%zsinh, :'SINH],
['%zcosh, :'COSH],
['%ztanh, :'TANH],
['%zasinh, :'ASINH],
['%zacosh, :'ACOSH],
['%zatanh, :'ATANH],
-- string operations
['%f2s, :'DFLOAT_-FORMAT_-GENERAL],
-- list contants
-- ['%nil, :'NIL],
-- unary list operations
['%head, :'CAR],
['%pair, :'CONS],
['%lempty?, :'NULL],
['%lfirst, :'CAR],
['%llength, :'LIST_-LENGTH],
['%lreverse, :'REVERSE],
['%lreverse_!,:'NREVERSE],
['%lsecond, :'CADR],
['%lthird, :'CADDR],
['%pair?, :'CONSP],
['%tail, :'CDR],
-- binary list operations
['%lconcat, :'APPEND],
-- simple vector operations
['%vfill, :'FILL],
['%vlength, :'sizeOfSimpleArray],
['%vector, :'VECTOR],
['%vref, :'SVREF],
['%aref, :'getSimpleArrayEntry],
['%makevector,:'MAKE_-ARRAY],
-- symbol unary functions
['%gensym, :'GENSYM],
['%sname, :'SYMBOL_-NAME],
['%ident?, :'IDENTP],
['%property,:'GET],
-- string functions
['%string?, :'STRINGP],
['%strlength, :'LENGTH],
['%schar, :'CHAR],
['%strconc, :'STRCONC],
['%strcopy, :'COPY_-SEQ],
-- general utility
['%hash, :'SXHASH],
['%equal, :'EQUAL],
['%tref, :'shellEntry],
['%sptreq, :'EQL], -- system pointer equality
['%lam, :'LAMBDA],
['%leave, :'RETURN],
['%otherwise,:'T],
['%funcall, :'FUNCALL],
['%when, :'COND]
] repeat property(first x,'%Rename) := rest x
++ Table of opcode-expander pairs.
for x in [
['%list, :function expandList],
['%collect, :function expandCollect],
['%loop, :function expandLoop],
['%return, :function expandReturn],
['%bcompl, :function expandBcompl],
['%ccst, :function expandCcst],
['%s2c, :function expandS2c],
['%ieq, :function expandIeq],
['%igt, :function expandIgt],
['%ilt, :function expandIlt],
['%ineg, :function expandIneg],
['%idivide, :function expandIdivide],
['%i2f, :function expandI2f],
['%fbase, :function expandFbase],
['%feq, :function expandFeq],
['%fgt, :function expandFgt],
['%flt, :function expandFlt],
['%fmaxval, :function expandFmaxval],
['%fminval, :function expandFminval],
['%fneg, :function expandFneg],
['%fprec, :function expandFprec],
['%fcstpi, :function expandFcstpi],
['%fsqrt, :function expandFsqrt],
['%fpowf, :function expandFpowf],
['%flog, :function expandFlog],
['%flog2, :function expandFlog2],
['%flog10, :function expandFlog10],
['%fasin, :function expandFasin],
['%facos, :function expandFacos],
['%facosh, :function expandFacosh],
['%fatanh, :function expandFatanh],
['%facoth, :function expandFacoth],
['%z2val, :function expandZ2val],
['%val2z, :function expandVal2z],
['%streq, :function expandStreq],
['%strlt, :function expandStrlt],
['%strstc, :function expandStrstc],
['%bitvecnot, :function expandBitvecnot],
['%bitvecand, :function expandBitvecand],
['%bitvecnand, :function expandBitvecnand],
['%bitvecor, :function expandBitvecor],
['%bitvecxor, :function expandBitvecxor],
['%bitvecnor, :function expandBitvecnor],
['%bitveclength, :function expandBitveclength],
['%bitveccopy, :function expandBitveccopy],
['%bitvecconc, :function expandBitvecconc],
['%bitveceq, :function expandBitveceq],
['%bitveclt, :function expandBitveclt],
['%bitvecref, :function expandBitvecref],
['%bitvector, :function expandBitvector],
['%peq, :function expandPeq],
['%before?, :function expandBefore?],
['%bind, :function expandBind],
['%store, :function expandStore],
['%dynval, :function expandDynval],
['%throw, :function expandThrow],
['%try, :function expandTry]
] repeat property(first x,'%Expander) := rest x
++ Return the expander of a middle-end opcode, or nil if there is none.
getOpcodeExpander op ==
op has %Expander
++ Expand all opcodes contained in the form `x' into a form
++ suitable for evaluation by the VM.
expandToVMForm x ==
x = '%false or x = '%nil => 'NIL
IDENTP x and (x' := x has %Rename) => x'
atomic? x => x
[op,:args] := x
IDENTP op and (fun:= getOpcodeExpander op) => apply(fun,x,nil)
op' := expandToVMForm op
args' := expandToVMForm args
EQ(op,op') and EQ(args,args') => x
[op',:args']
++ Evaluate an OpenAxiom VM form. Eventually, this function is
++ to be provided as a builtin by a OpenAxiom target machine.
eval x ==
EVAL expandToVMForm x
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