! Copyright (C) 2004, 2007 Slava Pestov. ! See http://factorcode.org/license.txt for BSD license. USING: arrays generic assocs inference inference.class inference.dataflow inference.backend io kernel math namespaces sequences vectors words quotations hashtables combinators classes generic.math continuations optimizer.def-use optimizer.pattern-match generic.standard ; IN: optimizer.backend SYMBOL: class-substitutions SYMBOL: literal-substitutions SYMBOL: value-substitutions SYMBOL: optimizer-changed GENERIC: optimize-node* ( node -- node/t changed? ) : ?union ( hash/f hash -- hash ) over [ union ] [ nip ] if ; : add-node-literals ( hash node -- ) over assoc-empty? [ 2drop ] [ [ node-literals ?union ] keep set-node-literals ] if ; : add-node-classes ( hash node -- ) over assoc-empty? [ 2drop ] [ [ node-classes ?union ] keep set-node-classes ] if ; : substitute-values ( assoc node -- ) over assoc-empty? [ 2drop ] [ 2dup node-in-d substitute 2dup node-in-r substitute 2dup node-out-d substitute node-out-r substitute ] if ; : perform-substitutions ( node -- ) class-substitutions get over add-node-classes literal-substitutions get over add-node-literals value-substitutions get swap substitute-values ; DEFER: optimize-nodes : optimize-children ( node -- ) [ dup node-children dup [ [ optimize-nodes ] map swap set-node-children ] [ 2drop ] if ] when* ; : optimize-node ( node -- node ) dup [ dup perform-substitutions dup optimize-node* [ nip optimizer-changed on optimize-node ] [ dup t eq? [ drop dup optimize-children ] [ nip optimize-node ] if ] if ] when ; M: f set-node-successor 2drop ; : (optimize-nodes) ( prev node -- ) optimize-node [ dup rot set-node-successor dup node-successor (optimize-nodes) ] [ f swap set-node-successor ] if* ; : optimize-nodes ( node -- newnode ) [ class-substitutions [ clone ] change literal-substitutions [ clone ] change dup [ optimize-node dup dup node-successor (optimize-nodes) ] when optimizer-changed get ] with-scope optimizer-changed set ; : prune-if ( node quot -- successor/t ) over >r call [ r> node-successor t ] [ r> drop t f ] if ; inline ! Generic nodes M: node optimize-node* drop t f ; M: #shuffle optimize-node* [ dup node-in-d empty? swap node-out-d empty? and ] prune-if ; M: #push optimize-node* [ node-out-d empty? ] prune-if ; : cleanup-inlining ( node -- newnode changed? ) node-successor [ node-successor t ] [ t f ] if* ; ! #return M: #return optimize-node* cleanup-inlining ; ! #values M: #values optimize-node* cleanup-inlining ; ! #>r M: #>r optimize-node* [ node-in-d empty? ] prune-if ; ! #r> M: #r> optimize-node* [ node-in-r empty? ] prune-if ; ! Some utilities for splicing in dataflow IR subtrees : follow ( key assoc -- value ) 2dup at* [ swap follow nip ] [ 2drop ] if ; : union* ( assoc1 assoc2 -- assoc ) union [ keys ] keep [ dupd follow ] curry H{ } map>assoc ; : update* ( assoc1 assoc2 -- ) #! Not very efficient. dupd union* update ; : post-inline ( #call/#merge #return/#values -- assoc ) >r node-out-d r> node-in-d 2array unify-lengths flip [ = not ] assoc-subset >hashtable ; : substitute-def-use ( node -- ) #! As a first approximation, we take all the values used #! by the set of new nodes, and push a 't' on their #! def-use list here. We could perform a full graph #! substitution, but we don't need to, because the next #! optimizer iteration will do that. We just need a minimal #! degree of accuracy; the new values should be marked as #! having _some_ usage, so that flushing doesn't erronously #! flush them away. [ compute-def-use def-use get keys ] with-scope def-use get [ [ t swap ?push ] change-at ] curry each ; : substitute-node ( old new -- ) #! The last node of 'new' becomes 'old', then values are #! substituted. A subsequent optimizer phase kills the #! last node of 'new' and the first node of 'old'. dup substitute-def-use last-node class-substitutions get over node-classes update literal-substitutions get over node-literals update 2dup post-inline value-substitutions get swap update* set-node-successor ; GENERIC: remember-method* ( method-spec node -- ) M: #call remember-method* [ node-history ?push ] keep set-node-history ; M: node remember-method* 2drop ; : remember-method ( method-spec node -- ) swap dup [ [ swap remember-method* ] curry each-node ] [ 2drop ] if ; : (splice-method) ( #call method-spec quot -- node ) #! Must remember the method before splicing in, otherwise #! the rest of the IR will also remember the method pick node-in-d dataflow-with [ remember-method ] keep [ swap infer-classes/node ] 2keep [ substitute-node ] keep ; : splice-quot ( #call quot -- node ) f swap (splice-method) ; : drop-inputs ( node -- #shuffle ) node-in-d clone \ #shuffle in-node ; ! Constant branch folding : fold-branch ( node branch# -- node ) over drop-inputs >r over node-children nth swap node-successor over substitute-node r> [ set-node-successor ] keep ; ! #if : known-boolean-value? ( node value -- value ? ) 2dup node-literal? [ node-literal t ] [ node-class { { [ dup null class< ] [ drop f f ] } { [ dup general-t class< ] [ drop t t ] } { [ dup \ f class< ] [ drop f t ] } { [ t ] [ drop f f ] } } cond ] if ; M: #if optimize-node* dup dup node-in-d first known-boolean-value? [ 0 1 ? fold-branch t ] [ 2drop t f ] if ; M: #dispatch optimize-node* dup dup node-in-d first 2dup node-literal? [ node-literal fold-branch t ] [ 3drop t f ] if ; ! #call : splice-method ( #call method-spec/t quot/t -- node/t ) #! t indicates failure { { [ dup t eq? ] [ 3drop t ] } { [ pick pick swap node-history member? ] [ 3drop t ] } { [ t ] [ (splice-method) ] } } cond ; ! Single dispatch method inlining optimization : already-inlined? ( node -- ? ) #! Was this node inlined from definition of 'word'? dup node-param swap node-history memq? ; : specific-method ( class word -- class ) order min-class ; : node-class# ( node n -- class ) over node-in-d ?nth node-class ; : dispatching-class ( node word -- class ) [ dispatch# node-class# ] keep specific-method ; : will-inline-method ( node word -- method-spec/t quot/t ) #! t indicates failure tuck dispatching-class dup [ swap [ 2array ] 2keep method method-def ] [ 2drop t t ] if ; : inline-standard-method ( node word -- node ) dupd will-inline-method splice-method ; ! Partial dispatch of math-generic words : math-both-known? ( word left right -- ? ) math-class-max swap specific-method ; : will-inline-math-method ( word left right -- method-spec/t quot/t ) #! t indicates failure 3dup math-both-known? [ [ 3array ] 3keep math-method ] [ 3drop t t ] if ; : inline-math-method ( #call word -- node ) over node-input-classes first2 will-inline-math-method splice-method ; : inline-method ( #call -- node ) dup node-param { { [ dup standard-generic? ] [ inline-standard-method ] } { [ dup math-generic? ] [ inline-math-method ] } { [ t ] [ 2drop t ] } } cond ; ! Resolve type checks at compile time where possible : comparable? ( actual testing -- ? ) #! If actual is a subset of testing or if the two classes #! are disjoint, return t. 2dup class< >r classes-intersect? not r> or ; : optimize-predicate? ( #call -- ? ) dup node-param "predicating" word-prop dup [ >r node-class-first r> comparable? ] [ 2drop f ] if ; : literal-quot ( node literals -- quot ) #! Outputs a quotation which drops the node's inputs, and #! pushes some literals. >r node-in-d length \ drop r> [ literalize ] map append >quotation ; : inline-literals ( node literals -- node ) #! Make #shuffle -> #push -> #return -> successor dupd literal-quot splice-quot ; : optimize-predicate ( #call -- node ) dup node-param "predicating" word-prop >r dup node-class-first r> class< 1array inline-literals ; : optimizer-hooks ( node -- conditions ) node-param "optimizer-hooks" word-prop ; : optimizer-hook ( node -- pair/f ) dup optimizer-hooks [ first call ] find 2nip ; : optimize-hook ( node -- ) dup optimizer-hook second call ; : define-optimizers ( word optimizers -- ) "optimizer-hooks" set-word-prop ; : flush-eval? ( #call -- ? ) dup node-param "flushable" word-prop [ node-out-d [ unused? ] all? ] [ drop f ] if ; : flush-eval ( #call -- node ) dup node-out-d length f inline-literals ; : partial-eval? ( #call -- ? ) dup node-param "foldable" word-prop [ dup node-in-d [ node-literal? ] curry* all? ] [ drop f ] if ; : literal-in-d ( #call -- inputs ) dup node-in-d [ node-literal ] curry* map ; : partial-eval ( #call -- node ) dup literal-in-d over node-param 1quotation [ with-datastack ] catch [ 3drop t ] [ inline-literals ] if ; : define-identities ( words identities -- ) [ "identities" set-word-prop ] curry each ; : find-identity ( node -- quot ) [ node-param "identities" word-prop ] keep [ swap first in-d-match? ] curry find nip dup [ second ] when ; : apply-identities ( node -- node/f ) dup find-identity dup [ splice-quot ] [ 2drop f ] if ; : optimistic-inline? ( #call -- ? ) dup node-param "specializer" word-prop dup [ >r node-input-classes r> length tail* [ types length 1 = ] all? ] [ 2drop f ] if ; : optimistic-inline ( #call -- node ) dup node-param word-def splice-quot ; M: #call optimize-node* { { [ dup flush-eval? ] [ flush-eval ] } { [ dup partial-eval? ] [ partial-eval ] } { [ dup find-identity ] [ apply-identities ] } { [ dup optimizer-hook ] [ optimize-hook ] } { [ dup optimize-predicate? ] [ optimize-predicate ] } { [ dup optimistic-inline? ] [ optimistic-inline ] } { [ t ] [ inline-method ] } } cond dup not ;