Recursion: Difference between revisions
(→Tail call elimination: Tail call elimination note) |
(→Language support: Add personal opinion) |
||
| (36 intermediate revisions by the same user not shown) | |||
| Line 1: | Line 1: | ||
[[Category:Research]] | |||
Recursion is a fantastic and often ignored feature of programming languages. Most introductions show an example you'd never use in practice, so this article is my attempt at showing some better ones using Lua. | |||
==Loops== | |||
Recursion can create loops without language constructs. | |||
== | |||
Here's an infinite loop: | |||
function infinite_loop() | |||
print("Hello there!") | |||
return infinite_loop() | |||
end | |||
infinite_loop() | |||
- | This is a bit longer than a non-recursive example. | ||
== | Here's a counting loop: | ||
- | function count_down(number) | ||
if number == 0 then return end | |||
print(number) | |||
return count_down(number - 1) | |||
end | |||
count_down(100) | |||
- | A non-recursive version of this would likely use some kind of for or while loop. | ||
Here's a loop that asks a user to pick a valid choice: | |||
function get_choice(choices) | |||
local line = io.read() | |||
choice = choices[line] | |||
if choice then | |||
return choice | |||
else | |||
print("Invalid choice! Try again") | |||
return get_choice(choices) | |||
end | |||
end | |||
print("Select a letter to get a number: A, B, C") | |||
choice = get_choice({A=1, B=2, C=3}) | |||
print("You picked number " .. choice) | |||
Without recursion this code would look a lot more confusing, at least to me. | |||
==State machines== | ==State machines== | ||
Not all recursion has to be direct. Indirect recursion lets you represent state machines easily. | |||
== | Here's a tiny adventure game with the player choosing state transitions: | ||
function dark_room() | |||
print("You are in a dark room.") | |||
print("Pick a door: fuzzy or metal") | |||
choice = get_choice({fuzzy=1, metal=2}) | |||
if choice == 1 then return fuzzy_room() | |||
elseif choice == 2 then return metal_room() | |||
end | |||
end | |||
function fuzzy_room() | |||
print("This room feels pretty fuzzy...") | |||
print("Pick a door: dark, metal") | |||
choice = get_choice({dark=1, metal=2}) | |||
if choice == 1 then return dark_room() | |||
elseif choice == 2 then return metal_room() | |||
end | |||
end | |||
function metal_room() | |||
print("This room feels really metallic.") | |||
print("Pick a door: dark, fuzzy or win") | |||
choice = get_choice({dark=1, fuzzy=2, win=3}) | |||
if choice == 1 then return dark_room() | |||
elseif choice == 2 then return fuzzy_room() | |||
elseif choice == 3 then return metal_room() | |||
end | |||
end | |||
function win_room() | |||
print("You found the treasure!") | |||
return | |||
end | |||
dark_room() | |||
Without recursion you'd likely need to put everything in a single function with a loop and state variable. | |||
Some things just make more sense when implemented recursively, to me at least. | |||
== Tail call optimization == | |||
There is a caveat with recursive programs: Each function call takes up stack space. The deeper you recurse, the more likely you are to run out of stack space and crash your program. This makes recursion useless in most programming languages. | |||
However there is a compromise: If a return in a function is just a call to another function then that return call is a 'tail call'. Languages that implement tail call optimization will re-use the current function call's stack for the function you're calling, solving the issue of stack space. | |||
- | |||
All the examples on this page use tail calls and run in Lua which implements tail call optimization. This means every program on this page is immune to stack overflows. | |||
- tail | The 1977 [https://en.wikisource.org/wiki/Index:AIM-443.djvu AI Lab Memo 443] talks more broadly about how tail calls are like goto statements that you can pass arguments to. Huge shout-out to the folks at Wikisource that transcribed this to an accessible text form. | ||
The significant downside of tail call optimization is that it can make debugging more difficult as you lack a proper stack trace. | |||
==Language support== | |||
Despite languages slowly adding features from functional languages developed 40 years ago, tail call optimization is still unpopular. I'm guessing that the reason is because not many people see the use of recursion. | |||
Here's an incomplete list of languages that support it automatically: | |||
* Haskell | |||
- | * Erlang (and Elixir) | ||
*Any Scheme implementation (Chez Scheme, Chibi Scheme, Chicken Scheme, TinyScheme) | |||
*Lua (see [https://www.lua.org/pil/6.3.html Programming in Lua 6.3 - Proper Tail Calls]) | |||
*Steel Bank Common Lisp (See [http://www.sbcl.org/manual/#Debug-Tail-Recursion SBCL Debug Tail Recursion]) | |||
*Squirrel (See [http://squirrel-lang.org/squirreldoc/reference/language/threads.html Squirrel's Threads page]) | |||
*Racket (See [https://docs.racket-lang.org/guide/Lists__Iteration__and_Recursion.html#%28part._tail-recursion%29 The Racket Guide 2.3.3 - Tail Recursion]) | |||
Here's an incomplete list of languages that require explicit support: | |||
* Clang C and C++ (see the [https://clang.llvm.org/docs/AttributeReference.html#musttail Clang musttail attribute]) | |||
* Tcl (see [https://www.tcl.tk/man/tcl/TclCmd/tailcall.html Tcl's tailcall manual page]) | |||
*OCaml (See [https://ocaml.org/manual/attributes.html OCaml's tailcall attribute]) | |||
* Perl (See [https://perldoc.perl.org/functions/goto Perl's goto function], specifically the goto &NAME variant) | |||
*Unix (See [https://jeapostrophe.github.io/2012-05-28-exec-vs--post.html exec and Tail-call Optimization]) | |||
*Assembly (Instead of returning set up registers and jump) | |||
*Ruby (See [https://nithinbekal.com/posts/ruby-tco/ Ruby's tailcall_optimization compile option]) | |||
*Zig (See [https://ziglang.org/documentation/master/#call Zig's always_tail call option]) | |||
Here's an incomplete list of popular languages that don't support it: | |||
* C and C++ | |||
* Go | |||
* Rust | |||
* Swift | |||
* PHP | |||
*Python | |||
*Raku | |||
* Anything running on the JVM (Java, Clojure, Scala, Kotlin) | |||
* Anything running on .NET (C#, F#) | |||
* Anything running on WebAssembly | |||
* Anything JavaScript or transpiling to JavaScript (TypeScript, CoffeeScript) | |||
Things look decent for desktops, but not so much for phones or web browsers. | |||
Personally I lean towards the idea of languages adding new keywords or explicit support for this, such as a 'goto' or 'jump' keyword. It helps in a debugger when you have stack frames by default, and it helps make it clear that it's important that this tail call is optimized. | |||
Revision as of 06:29, 13 October 2022
Recursion is a fantastic and often ignored feature of programming languages. Most introductions show an example you'd never use in practice, so this article is my attempt at showing some better ones using Lua.
Loops
Recursion can create loops without language constructs.
Here's an infinite loop:
function infinite_loop()
print("Hello there!")
return infinite_loop()
end
infinite_loop()
This is a bit longer than a non-recursive example.
Here's a counting loop:
function count_down(number) if number == 0 then return end print(number) return count_down(number - 1) end count_down(100)
A non-recursive version of this would likely use some kind of for or while loop.
Here's a loop that asks a user to pick a valid choice:
function get_choice(choices)
local line = io.read()
choice = choices[line]
if choice then
return choice
else
print("Invalid choice! Try again")
return get_choice(choices)
end
end
print("Select a letter to get a number: A, B, C")
choice = get_choice({A=1, B=2, C=3})
print("You picked number " .. choice)
Without recursion this code would look a lot more confusing, at least to me.
State machines
Not all recursion has to be direct. Indirect recursion lets you represent state machines easily.
Here's a tiny adventure game with the player choosing state transitions:
function dark_room()
print("You are in a dark room.")
print("Pick a door: fuzzy or metal")
choice = get_choice({fuzzy=1, metal=2})
if choice == 1 then return fuzzy_room()
elseif choice == 2 then return metal_room()
end
end
function fuzzy_room()
print("This room feels pretty fuzzy...")
print("Pick a door: dark, metal")
choice = get_choice({dark=1, metal=2})
if choice == 1 then return dark_room()
elseif choice == 2 then return metal_room()
end
end
function metal_room()
print("This room feels really metallic.")
print("Pick a door: dark, fuzzy or win")
choice = get_choice({dark=1, fuzzy=2, win=3})
if choice == 1 then return dark_room()
elseif choice == 2 then return fuzzy_room()
elseif choice == 3 then return metal_room()
end
end
function win_room()
print("You found the treasure!")
return
end
dark_room()
Without recursion you'd likely need to put everything in a single function with a loop and state variable.
Some things just make more sense when implemented recursively, to me at least.
Tail call optimization
There is a caveat with recursive programs: Each function call takes up stack space. The deeper you recurse, the more likely you are to run out of stack space and crash your program. This makes recursion useless in most programming languages.
However there is a compromise: If a return in a function is just a call to another function then that return call is a 'tail call'. Languages that implement tail call optimization will re-use the current function call's stack for the function you're calling, solving the issue of stack space.
All the examples on this page use tail calls and run in Lua which implements tail call optimization. This means every program on this page is immune to stack overflows.
The 1977 AI Lab Memo 443 talks more broadly about how tail calls are like goto statements that you can pass arguments to. Huge shout-out to the folks at Wikisource that transcribed this to an accessible text form.
The significant downside of tail call optimization is that it can make debugging more difficult as you lack a proper stack trace.
Language support
Despite languages slowly adding features from functional languages developed 40 years ago, tail call optimization is still unpopular. I'm guessing that the reason is because not many people see the use of recursion.
Here's an incomplete list of languages that support it automatically:
- Haskell
- Erlang (and Elixir)
- Any Scheme implementation (Chez Scheme, Chibi Scheme, Chicken Scheme, TinyScheme)
- Lua (see Programming in Lua 6.3 - Proper Tail Calls)
- Steel Bank Common Lisp (See SBCL Debug Tail Recursion)
- Squirrel (See Squirrel's Threads page)
- Racket (See The Racket Guide 2.3.3 - Tail Recursion)
Here's an incomplete list of languages that require explicit support:
- Clang C and C++ (see the Clang musttail attribute)
- Tcl (see Tcl's tailcall manual page)
- OCaml (See OCaml's tailcall attribute)
- Perl (See Perl's goto function, specifically the goto &NAME variant)
- Unix (See exec and Tail-call Optimization)
- Assembly (Instead of returning set up registers and jump)
- Ruby (See Ruby's tailcall_optimization compile option)
- Zig (See Zig's always_tail call option)
Here's an incomplete list of popular languages that don't support it:
- C and C++
- Go
- Rust
- Swift
- PHP
- Python
- Raku
- Anything running on the JVM (Java, Clojure, Scala, Kotlin)
- Anything running on .NET (C#, F#)
- Anything running on WebAssembly
- Anything JavaScript or transpiling to JavaScript (TypeScript, CoffeeScript)
Things look decent for desktops, but not so much for phones or web browsers.
Personally I lean towards the idea of languages adding new keywords or explicit support for this, such as a 'goto' or 'jump' keyword. It helps in a debugger when you have stack frames by default, and it helps make it clear that it's important that this tail call is optimized.