Difference between revisions of "Why Tailcalls"
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=== guaranteed disposal of stack-frame === | === guaranteed disposal of stack-frame === | ||
Clojure needs workarounds to avoid floating garbage | Clojure needs workarounds to avoid floating garbage | ||
+ | public static int count(Object o) { | ||
+ | if (o instanceof Counted) | ||
+ | return ((Counted) o).count(); | ||
+ | return countFrom(Util.ret1(o, o = null)); | ||
+ | } | ||
+ | static public Object ret1(Object ret, Object nil) { return ret; } | ||
=== Kōan === | === Kōan === |
Revision as of 11:49, 28 July 2010
Are tailcalls fated to come in second place on every feature priority list?
Let's gather the use cases and consider the implementation.
(Note: This page is about "hard tail calls" as defined in the Rose blog. Soft TCO is already in many compilers, but does not have a strong effect on software architecture.)
Contents
use cases
multi-core task distribution
(Doug Lea) chaining task execution; without tail calls you blow the stack needlessly
languages with guaranteed TCO
These are languages with functional patterns, including Scheme, Scala, F#. Seph also aims to give this guarantee.
guaranteed disposal of stack-frame
Clojure needs workarounds to avoid floating garbage
public static int count(Object o) { if (o instanceof Counted) return ((Counted) o).count(); return countFrom(Util.ret1(o, o = null)); } static public Object ret1(Object ret, Object nil) { return ret; }
Kōan
Tail call... Booty call... More than a coincidence? You decide.