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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 def
namespace BOOT
--%
$optimizableConstructorNames := $SystemInlinableConstructorNames
++ Return true if the domain `dom' is an instance of a functor
++ that has been nominated for inlining.
optimizableDomain? dom ==
opOf dom in $optimizableConstructorNames
++ Register the domain `dom' for inlining.
nominateForInlining dom ==
$optimizableConstructorNames := [opOf dom,:$optimizableConstructorNames]
--%
++ return the template of the instantiating functor for
++ the domain form `dom'.
getDomainTemplate dom ==
atom dom => nil
getInfovec first dom
++ Emit code for an indirect call to domain-wide Spad function.
++ This is usually the case for exported functions.
emitIndirectCall(fn,args,x) ==
rplac(first x, "SPADCALL")
rplac(first fn,"getShellEntry")
rplac(rest x, [:args,fn])
x
--% OPTIMIZER
optimizeFunctionDef(def) ==
if $reportOptimization then
sayBrightlyI bright '"Original LISP code:"
pp def
def' := optimize COPY def
if $reportOptimization then
sayBrightlyI bright '"Optimized LISP code:"
pp def'
[name,[slamOrLam,args,body]] := def'
body':=
removeTopLevelCatch body where
removeTopLevelCatch body ==
body is ["CATCH",g,u] =>
removeTopLevelCatch replaceThrowByReturn(u,g)
body
replaceThrowByReturn(x,g) ==
fn(x,g)
x
fn(x,g) ==
x is ["THROW", =g,:u] =>
rplac(first x,"RETURN")
rplac(rest x,replaceThrowByReturn(u,g))
atom x => nil
replaceThrowByReturn(first x,g)
replaceThrowByReturn(rest x,g)
[name,[slamOrLam,args,body']]
optimize x ==
(opt x; x) where
opt x ==
atom x => nil
(y:= first x)='QUOTE => nil
y='CLOSEDFN => nil
y is [["XLAM",argl,body],:a] =>
optimize rest x
argl = "ignore" => RPLAC(first x,body)
if not (LENGTH argl<=LENGTH a) then
SAY '"length mismatch in XLAM expression"
PRETTYPRINT y
RPLAC(first x,optimize optXLAMCond SUBLIS(pairList(argl,a),body))
atom y =>
optimize rest x
if first y="IF" then (RPLAC(first x,optIF2COND y); y:= first x)
op:= GETL(subrname first y,"OPTIMIZE") =>
(optimize rest x; RPLAC(first x,FUNCALL(op,optimize first x)))
RPLAC(first x,optimize first x)
optimize rest x
subrname u ==
IDENTP u => u
COMPILED_-FUNCTION_-P u or MBPIP u => BPINAME u
nil
changeThrowToExit(s,g) ==
atom s or first s in '(QUOTE SEQ REPEAT COLLECT) => nil
s is ["THROW", =g,:u] => (rplac(first s,"EXIT"); rplac(rest s,u))
changeThrowToExit(first s,g)
changeThrowToExit(rest s,g)
hasNoThrows(a,g) ==
a is ["THROW", =g,:.] => false
atom a => true
hasNoThrows(first a,g) and hasNoThrows(rest a,g)
changeThrowToGo(s,g) ==
atom s or first s='QUOTE => nil
s is ["THROW", =g,u] =>
changeThrowToGo(u,g)
rplac(first s,"PROGN")
rplac(rest s,[["%LET",second g,u],["GO",second g]])
changeThrowToGo(first s,g)
changeThrowToGo(rest s,g)
optCatch (x is ["CATCH",g,a]) ==
$InteractiveMode => x
atom a => a
if a is ["SEQ",:s,["THROW", =g,u]] then
changeThrowToExit(s,g)
rplac(rest a,[:s,["EXIT",u]])
["CATCH",y,a]:= optimize x
if hasNoThrows(a,g) then
rplac(first x,first a)
rplac(rest x,rest a)
else
changeThrowToGo(a,g)
rplac(first x,"SEQ")
rplac(rest x,[["EXIT",a],second g,["EXIT",second g]])
x
optSPADCALL(form is ['SPADCALL,:argl]) ==
null $InteractiveMode => form
-- last arg is function/env, but may be a form
argl is [:argl,fun] and fun is ["ELT",dom,slot] =>
optCall ["%Call",['ELT,dom,slot],:argl]
form
optCall (x is ["%Call",:u]) ==
-- destructively optimizes this new x
x:= optimize [u]
-- next should happen only as result of macro expansion
atom first x => first x
[fn,:a]:= first x
atom fn => (RPLAC(rest x,a); RPLAC(first x,fn))
fn is ["applyFun",name] =>
(RPLAC(first x,"SPADCALL"); RPLAC(rest x,[:a,name]); x)
fn is [q,R,n] and q in '(getShellEntry ELT QREFELT CONST) =>
not $bootStrapMode and (w:= optCallSpecially(q,x,n,R)) => w
q="CONST" => ["spadConstant",R,n]
emitIndirectCall(fn,a,x)
systemErrorHere ["optCall",x]
optCallSpecially(q,x,n,R) ==
y:= LASSOC(R,$specialCaseKeyList) => optSpecialCall(x,y,n)
optimizableDomain? R => optSpecialCall(x,R,n)
(y:= get(R,"value",$e)) and
optimizableDomain? y.expr =>
optSpecialCall(x,y.expr,n)
(
(y:= lookup(R,$getDomainCode)) and ([op,y,prop]:= y) and
(yy:= LASSOC(y,$specialCaseKeyList)) =>
optSpecialCall(x,[op,yy,prop],n)) where
lookup(a,l) ==
null l => nil
[l',:l]:= l
l' is ["%LET", =a,l',:.] => l'
lookup(a,l)
nil
optCallEval u ==
u is ["List",:.] => List Integer()
u is ["Vector",:.] => Vector Integer()
u is ["PrimitiveArray",:.] => PrimitiveArray Integer()
u is ["FactoredForm",:.] => FactoredForm Integer()
u is ["Matrix",:.] => Matrix Integer()
eval u
optCons (x is ["CONS",a,b]) ==
a="NIL" =>
b='NIL => (rplac(first x,'QUOTE); rplac(rest x,['NIL,:'NIL]); x)
b is ['QUOTE,:c] => (rplac(first x,'QUOTE); rplac(rest x,['NIL,:c]); x)
x
a is ['QUOTE,a'] =>
b='NIL => (rplac(first x,'QUOTE); rplac(rest x,[a',:'NIL]); x)
b is ['QUOTE,:c] => (rplac(first x,'QUOTE); rplac(rest x,[a',:c]); x)
x
x
optSpecialCall(x,y,n) ==
yval := optCallEval y
CAAAR x="CONST" =>
KAR yval.n = function Undef =>
keyedSystemError("S2GE0016",['"optSpecialCall",
'"invalid constant"])
MKQ yval.n
fn := getFunctionReplacement compileTimeBindingOf first yval.n =>
rplac(rest x,CDAR x)
rplac(first x,fn)
if fn is ["XLAM",:.] then x:=first optimize [x]
x is ["EQUAL",:args] => RPLACW(x,DEF_-EQUAL args)
--DEF-EQUAL is really an optimiser
x
[fn,:a]:= first x
emitIndirectCall(fn,a,x)
compileTimeBindingOf u ==
null(name:= BPINAME u) => keyedSystemError("S2OO0001",[u])
name="Undef" => MOAN "optimiser found unknown function"
name
optMkRecord ["mkRecord",:u] ==
u is [x] => ["LIST",x]
#u=2 => ["CONS",:u]
["VECTOR",:u]
optCond (x is ['COND,:l]) ==
if l is [a,[aa,b]] and TruthP aa and b is ["COND",:c] then
RPLACD(rest x,c)
if l is [[p1,:c1],[p2,:c2],:.] then
if (p1 is ["NOT",=p2]) or (p2 is ["NOT",=p1]) then
l:=[[p1,:c1],['(QUOTE T),:c2]]
RPLACD( x,l)
c1 is ['NIL] and p2 = '(QUOTE T) and first c2 = '(QUOTE T) =>
p1 is ["NOT",p1']=> return p1'
return ["NOT",p1]
l is [[p1,:c1],[p2,:c2],[p3,:c3]] and TruthP p3 =>
EqualBarGensym(c1,c3) =>
["COND",[["OR",p1,["NOT",p2]],:c1],[['QUOTE,true],:c2]]
EqualBarGensym(c1,c2) => ["COND",[["OR",p1,p2],:c1],[['QUOTE,true],:c3]]
x
for y in tails l repeat
while y is [[a1,c1],[a2,c2],:y'] and EqualBarGensym(c1,c2) repeat
a:=['OR,a1,a2]
RPLAC(first first y,a)
RPLAC(rest y,y')
x
AssocBarGensym(key,l) ==
for x in l repeat
cons? x =>
EqualBarGensym(key,first x) => return x
EqualBarGensym(x,y) ==
$GensymAssoc: fluid := nil
fn(x,y) where
fn(x,y) ==
x=y => true
GENSYMP x and GENSYMP y =>
z:= assoc(x,$GensymAssoc) => y=rest z
$GensymAssoc:= [[x,:y],:$GensymAssoc]
true
null x => y is [g] and GENSYMP g
null y => x is [g] and GENSYMP g
atom x or atom y => false
fn(first x,first y) and fn(rest x,rest y)
--Called early, to change IF to COND
optIF2COND ["IF",a,b,c] ==
b is "%noBranch" => ["COND",[["NOT",a],c]]
c is "%noBranch" => ["COND",[a,b]]
c is ["IF",:.] => ["COND",[a,b],:rest optIF2COND c]
c is ["COND",:p] => ["COND",[a,b],:p]
["COND",[a,b],[$true,c]]
optXLAMCond x ==
x is ["COND",u:= [p,c],:l] =>
(optPredicateIfTrue p => c; ["COND",u,:optCONDtail l])
atom x => x
RPLAC(first x,optXLAMCond first x)
RPLAC(rest x,optXLAMCond rest x)
x
optPredicateIfTrue p ==
p is ['QUOTE,:.] => true
p is [fn,x] and MEMQ(fn,$BasicPredicates) and FUNCALL(fn,x) => true
nil
optCONDtail l ==
null l => nil
[frst:= [p,c],:l']:= l
optPredicateIfTrue p => [[$true,c]]
null rest l => [frst,[$true,["CondError"]]]
[frst,:optCONDtail l']
optSEQ ["SEQ",:l] ==
tryToRemoveSEQ SEQToCOND getRidOfTemps splicePROGN l where
splicePROGN l ==
isAtomicForm l => l
l is [["PROGN",:stmts],:l'] => [:stmts,:l']
rplac(rest l, splicePROGN rest l)
getRidOfTemps l ==
null l => nil
l is [["%LET",g,x,:.],:r] and GENSYMP g and 2>numOfOccurencesOf(g,r) =>
getRidOfTemps substitute(x,g,r)
first l="/throwAway" => getRidOfTemps rest l
--this gets rid of unwanted labels generated by declarations in SEQs
[first l,:getRidOfTemps rest l]
SEQToCOND l ==
transform:= [[a,b] for x in l while (x is ["COND",[a,["EXIT",b]]])]
before:= take(#transform,l)
aft:= after(l,before)
null before => ["SEQ",:aft]
null aft => ["COND",:transform,'((QUOTE T) (conderr))]
true => ["COND",:transform,['(QUOTE T),optSEQ ["SEQ",:aft]]]
tryToRemoveSEQ l ==
l is ["SEQ",[op,a]] and op in '(EXIT RETURN THROW) => a
l
optRECORDELT ["RECORDELT",name,ind,len] ==
len=1 =>
ind=0 => ["QCAR",name]
keyedSystemError("S2OO0002",[ind])
len=2 =>
ind=0 => ["QCAR",name]
ind=1 => ["QCDR",name]
keyedSystemError("S2OO0002",[ind])
["QVELT",name,ind]
optSETRECORDELT ["SETRECORDELT",name,ind,len,expr] ==
len=1 =>
ind=0 => ["PROGN",["RPLACA",name,expr],["QCAR",name]]
keyedSystemError("S2OO0002",[ind])
len=2 =>
ind=0 => ["PROGN",["RPLACA",name,expr],["QCAR",name]]
ind=1 => ["PROGN",["RPLACD",name,expr],["QCDR",name]]
keyedSystemError("S2OO0002",[ind])
["QSETVELT",name,ind,expr]
optRECORDCOPY ["RECORDCOPY",name,len] ==
len=1 => ["LIST",["CAR",name]]
len=2 => ["CONS",["CAR",name],["CDR",name]]
["REPLACE",["MAKE_-VEC",len],name]
--mkRecordAccessFunction(ind,len) ==
-- stringOfDs:= $EmptyString
-- for i in 0..(ind-1) do stringOfDs:= STRCONC(stringOfDs,PNAME "D")
-- prefix:= if ind=len-1 then PNAME "C" else PNAME "CA"
-- if $QuickCode then prefix:=STRCONC("Q",prefix)
-- INTERN(STRCONC(prefix,stringOfDs,PNAME "R"))
optSuchthat [.,:u] == ["SUCHTHAT",:u]
optMINUS u ==
u is ['MINUS,v] =>
NUMBERP v => -v
u
u
optQSMINUS u ==
u is ['QSMINUS,v] =>
NUMBERP v => -v
u
u
opt_- u ==
u is ['_-,v] =>
NUMBERP v => -v
u
u
optLESSP u ==
u is ['LESSP,a,b] =>
b = 0 => ['MINUSP,a]
['GREATERP,b,a]
u
++ List of VM side effect free operators.
$VMsideEffectFreeOperators ==
'(CAR CDR LENGTH SIZE EQUAL EQL EQ NOT NULL OR AND
SPADfirst QVELT _+ _- _* _< _= _<_= _> _>_= ASH INTEGER_-LENGTH
QEQCAR QCDR QCAR INTEGERP FLOATP STRINGP IDENTP SYMBOLP
MINUSP GREATERP ZEROP ODDP FLOAT_-RADIX FLOAT FLOAT_-SIGN FLOAT_-DIGITS
CGREATERP GGREATERP CHAR BOOLE GET BVEC_-GREATER FUNCALL)
++ List of simple VM operators
$simpleVMoperators ==
append($VMsideEffectFreeOperators,
["CONS","LIST","VECTOR","STRINGIMAGE",
"MAKE-FULL-CVEC","BVEC-MAKE-FULL","COND"])
++ Return true if the `form' is semi-simple with respect to
++ to the list of operators `ops'.
semiSimpleRelativeTo?(form,ops) ==
isAtomicForm form => true
form isnt [op,:args] or not MEMQ(op,ops) => false
and/[semiSimpleRelativeTo?(f,ops) for f in args]
++ Return true if `form' is a simple VM form.
++ See $simpleVMoperators for the definition of simple operators.
isSimpleVMForm form ==
semiSimpleRelativeTo?(form,$simpleVMoperators)
++ Return true if `form' is a VM form whose evaluation does not depend
++ on the program point where it is evaluated.
isFloatableVMForm: %Code -> %Boolean
isFloatableVMForm form ==
atom form => form ~= "$"
form is ["QUOTE",:.] => true
MEMQ(first form, $simpleVMoperators) and
"and"/[isFloatableVMForm arg for arg in rest form]
++ Return true if the VM form `form' is one that we certify to
++ evaluate to a (compile time) constant. Note that this is a
++ fairly conservative approximation of compile time constants.
isVMConstantForm: %Code -> %Boolean
isVMConstantForm form ==
integer? form or string? form => true
form=nil or form=true => true
form isnt [op,:args] => false
op = "QUOTE" => true
MEMQ(op,$simpleVMoperators) and
"and"/[isVMConstantForm arg for arg in args]
++ Return the set of free variables in the VM form `form'.
findVMFreeVars form ==
IDENTP form => [form]
form isnt [op,:args] => nil
op = "QUOTE" => nil
vars := union/[findVMFreeVars arg for arg in args]
atom op => vars
union(findVMFreeVars op,vars)
++ Return true is `var' is the left hand side of an assignment
++ in `form'.
varIsAssigned(var,form) ==
isAtomicForm form => false
form is [op,=var,:.] and op in '(%LET LETT SETQ) => true
or/[varIsAssigned(var,f) for f in form]
++ Subroutine of optLET. Return true if the variable `var' locally
++ defined in the LET-form can be safely replaced by its initalization
++ `expr' in the `body' of the LET-form.
canInlineVarDefinition(var,expr,body) ==
varIsAssigned(var,body) => false
numOfOccurencesOf(var,body) < 2 => true
atom expr and not varIsAssigned(expr,body)
++ Implement simple-minded LET-inlining. It seems we can't count
++ on Lisp implementations to do this simple transformation.
++ This transformation will probably be more effective when all
++ type informations are still around. Which is why we should
++ have a type directed compilation throughout.
optLET u ==
-- Hands off non-simple cases.
u isnt ["LET",inits,body] => u
-- Inline functionally used local variables with their initializers.
inits := [:newInit for (init := [var,expr]) in inits] where
newInit() ==
canInlineVarDefinition(var,expr,body) =>
body := substitute(expr,var,body)
nil -- remove this initialization
[init] -- otherwwise keep it.
null inits => body
rplac(second u,inits)
rplac(third u,body)
-- Avoid initialization forms that may not be floatable.
not(and/[isFloatableVMForm init for [.,init] in inits]) => u
-- Identity function.
inits is [[=body,init]] => init
-- Handle only most trivial operators.
body isnt [op,:args] => u
-- Well, with case-patterns, it is beneficial to try a bit harder
-- with conditional forms.
op = "COND" =>
continue := true -- shall be continue let-inlining?
-- Since we do a single pass, we can't reuse the inits list
-- as we may find later that we can't really inline into
-- all forms due to excessive conversatism. So we build a
-- substitution list ahead of time.
substPairs := [[var,:init] for [var,init] in inits]
for clauses in tails args while continue repeat
clause := first clauses
-- we do not attempt more complicated clauses yet.
clause isnt [test,stmt] => continue := false
-- Stop inlining at least one test is not simple
not isSimpleVMForm test => continue := false
rplac(first clause,SUBLIS(substPairs,test))
isSimpleVMForm stmt =>
rplac(second clause,SUBLIS(substPairs,stmt))
continue := false
continue => body
u
not MEMQ(op,$simpleVMoperators) => u
not(and/[isAtomicForm arg for arg in args]) => u
-- Inline only if all parameters are used. Get cute later.
not(and/[MEMQ(x,args) for [x,.] in inits]) => u
-- Munge inits into list of dotted-pairs. Lovely Lisp.
for defs in tails inits repeat
def := first defs
atom def => systemErrorHere ["optLET",def] -- cannot happen
rplac(rest def, second def)
SUBLIS(inits,body)
optLET_* form ==
form isnt ["LET*",:.] => form
ok := true
while ok for [[var,.],:inits] in tails second form repeat
if CONTAINED(var,inits) then ok := false
not ok => form
rplac(first form,"LET")
optLET form
optBind form ==
rplac(first form,"LET*")
optLET_* form
optLIST form ==
form is ["LIST"] => nil
form
optCollectVector form ==
[.,eltType,:iters,body] := form
fromList := false -- are we drawing from a list?
vecSize := nil -- size of vector
index := nil -- loop/vector index.
for iter in iters while not fromList repeat
[op,:.] := iter
op in '(SUCHTHAT WHILE UNTIL) => fromList := true
op in '(IN ON) => vecSize := [["SIZE",third iter],:vecSize]
op in '(STEP ISTEP) =>
-- pick a loop variable that we can use as the loop index.
[.,var,lo,inc,:etc] := iter
if lo = 0 and inc = 1 then
index := var
if [hi] := etc then
sz :=
inc = 1 =>
lo = 1 => hi
lo = 0 => MKQSADD1 hi
MKQSADD1 ["-",hi,lo]
lo = 1 => ["/",hi,inc]
lo = 0 => ["/",MKQSADD1 hi,inc]
["/",["-",MKQSADD1 hi, lo],inc]
vecSize := [sz, :vecSize]
systemErrorHere ["optCollectVector", iter]
-- if we draw from a list, then just build a list and convert to vector.
fromList =>
["homogeneousListToVector",["getVMType",eltType], ["COLLECT",:iters,body]]
vecSize = nil => systemErrorHere ["optCollectVector",form]
-- get the actual size of the vector.
vecSize :=
vecSize is [hi] => hi
["MIN",:nreverse vecSize]
-- if no suitable loop index was found, introduce one.
if index = nil then
index := GENSYM()
iters := [:iters,["ISTEP",index,0,1]]
vec := GENSYM()
["LET",[[vec,["makeSimpleArray",["getVMType",eltType],vecSize]]],
["REPEAT",:iters,["setSimpleArrayEntry",vec,index,body]],
vec]
++ Translate retraction of a value denoted by `e' to sub-domain `m'
++ defined by predicate `pred',
optRetract ["%Retract",e,m,pred] ==
atom e => ["check-subtype",substitute(e,"#1",pred),MKQ m,e]
g := GENSYM()
["LET",[[g,e]],["check-subtype",substitute(g,"#1",pred),MKQ m,g]]
lispize x == first optimize [x]
--% optimizer hash table
for x in '( (%Call optCall) _
(SEQ optSEQ)_
(LET optLET)_
(LET_* optLET_*)_
(%Bind optBind)_
(LIST optLIST)_
(MINUS optMINUS)_
(QSMINUS optQSMINUS)_
(_- opt_-)_
(LESSP optLESSP)_
(SPADCALL optSPADCALL)_
(_| optSuchthat)_
(CATCH optCatch)_
(COND optCond)_
(%Retract optRetract)_
(%CollectV optCollectVector)_
(mkRecord optMkRecord)_
(RECORDELT optRECORDELT)_
(SETRECORDELT optSETRECORDELT)_
(RECORDCOPY optRECORDCOPY)) _
repeat MAKEPROP(first x,'OPTIMIZE, second x)
--much quicker to call functions if they have an SBC
|