Returns a list containing the elements of its argument, list, in reverse order.
https://www.tcl-lang.org/man/tcl8.5/TclCmd/lreverse.htm
wdb Improvement proposal: add option -stride such that one can revert a list of coords {x0 y0 x1 y1 …} or {x0 y0 z0 x1 y1 z1 …}
Example:
proc myReverse {args} { set li [lindex $args end] set option [dict create -stride 1 {*}[lrange $args 0 end-1]] for {set i 0} {$i < [dict get $option -stride]} {incr i} { lappend argL arg$i } set cmd list foreach arg $argL { append cmd " \$$arg" } lappend lmapBody lmap $argL $li $cmd concat {*}[lreverse [eval $lmapBody]] }
How it works:
% myReverse {a b c d e f} f e d c b a % myReverse -stride 2 {a b c d e f} e f c d a b % myReverse -stride 3 {a b c d e f} d e f a b c %
Implemented in the changes in Tcl/Tk 8.5 as part of TIP #272[L1 ].
Downward compatible pure-Tcl version:
if {[info command lreverse] == ""} { proc lreverse list { set res {} set i [llength $list] while {$i} { lappend res [lindex $list [incr i -1]] } set res } ;# RS }
LEG: List reversion is used e.g. in functional programming map and reduce or fold respectively. Therefore execution time and memory requirements are important issues.
In fact the above Tcl version is the fastest implementation. To make backwards compatible code with lreverse you can use the following boilerplate code, which squeezes out some more microseconds by reducing one bracket evaluation in the loop.
if {[info command lreverse] == ""} { proc lreverse l { set r {} set i [llength $l] while {[incr i -1]} {lappend r [lindex $l $i]} lappend r [lindex $l 0] } }
AMG: The above code loops forever when given with an empty list.
LEG: At the moment of this writing there are little references to lreverse in the wiki, which indicates that until now, everybody has reverted his/her list 'by hand'.
The following is an ad nauseam exploration of pure-Tcl lreverse. You can just skip to the section Consolidated timing results for some numbers. There you find all implementations listed in order of execution time for a small list. It is very interesting to see, that the ordering by the second column - reverting a longer list - would be different. Obviously the builtin version wins by magnitudes, on long lists, since no function calls are needed between iterations. The main surprise however is, that the dumb concat/list implementation of lreverse2 scales much better on longer lists than lset and, worse, linsert which are used in lreverse6 and lreverse5 respectively. The big winner, however is the countdown while loop, which given in the above form is even slightly faster.
It would be interesting to time the tail recursive implementations lreverse7 and lreverse8 with Tail call optimization.
The use of the new (as in Tcl8.5) {*} syntax in lreverse8 does not provide better speed, the standard implemention with lindex/lrange in lreverse7 is arguably uglier but faster on long lists.
# LEG20081207: list reverse in comparison # default quiet version of : proc : args {} # verbose version of : proc : args {foreach arg $args {puts $arg}} : Introduction { This is a comparison of different Tcl implementations of the (Tcl 8.5) lreverse command. Each implementation is tested and timed with the following test string: } set l {1 {2 3} {4 {5 6}} 7} : $l : lreverse {First we test the builtin lreverse command} if {[catch {package require Tcl 8.5}]} { : {Sorry, lreverse is available from Tcl 8.5 or later only} { it seems, you are running an earlier version:} $tcl_version } else { puts "testing builtin: lreverse $l => [lreverse $l]" # preclude initial delay of time command time {lreverse $l} 1 puts [time {lreverse $l} 10000] } : lreverse1 { Is the implementation given by Richard Suchenwirth on the Tcler's Wiki https://wiki.tcl-lang.org/17188 } proc lreverse1 list { set res {} set i [llength $list] while {$i} {lappend res [lindex $list [incr i -1]]} set res } ;# RS puts "testing lreverse1 $l => [lreverse1 $l]" time {lreverse1 $l} 1 puts [time {lreverse1 $l} 10000] : lreverse2 { Is a minimal implementation based only on the basic Tcl list operators. Note: it does not use linsert and such loses time with an additional function call. } proc lreverse2 l { set r {} foreach e $l {set r [concat [list $e] $r]} set r } puts "testing lreverse2 $l => [lreverse2 $l]" time {lreverse2 $l} 1 puts [time {lreverse2 $l} 10000] : lreverse3 { Is an implementation using a for loop counting down from the end of the list. For all intents and purposes the same as lreverse1. } proc lreverse3 l { for {set i [llength $l]} {$i} {} { incr i -1 lappend r [lindex $l $i] } set r } puts "testing lreverse3 $l => [lreverse3 $l]" time {lreverse3 $l} 1 puts [time {lreverse3 $l} 10000] : lreverse4 { Is a recursive version. Especially for larger lists it would not work well. } proc lreverse4 l { if {[llength $l]==1} {return $l} concat [lreverse4 [lrange $l 1 end]] [list [lindex $l 0]] } puts "testing lreverse4 $l => [lreverse4 $l]" time {lreverse4 $l} 1 puts [time {lreverse4 $l} 10000] : lreverse5 { Uses the linsert command to stuff each element on top of the result list. } proc lreverse5 l { set r {} foreach e $l {set r [linsert $r 0 $e]} set r } puts "testing lreverse5 $l => [lreverse5 $l]" time {lreverse5 $l} 1 puts [time {lreverse5 $l} 10000] : lreverse6 { Uses the lset command, which appeared first in Tcl 8.4. } if {[catch {package require Tcl 8.4}]} { : {Sorry, lreverse is available from Tcl 8.4 or later only} { it seems, you are running an earlier version:} $tcl_version } else { proc lreverse6 l { set i [llength $l] foreach e $l { incr i -1 lset l $i $e } set l } puts "testing lreverse6 $l => [lreverse6 $l]" time {lreverse6 $l} 1 puts [time {lreverse6 $l} 10000] } : lreverse7 { Is a tail recursive version, which could gain speed over the normal recursion by tail call optimization, and work with arbitrary length lists. } proc lreverse7 {l {r {}}} { if {[llength $l]==1} { linsert $r 0 $l } else { lreverse7 \ [lrange $l 1 end] \ [linsert $r 0 [lindex $l 0]] } } puts "testing lreverse7 $l => [lreverse7 $l]" time {lreverse7 $l} 1 puts [time {lreverse7 $l} 10000] proc _lreverse8 {r f args} { if {[llength $args]} { _lreverse8 [linsert $r 0 $f] {*}$args } else { linsert $r 0 $f } } proc lreverse8 l {_lreverse8 {} {*}$l} puts "testing lreverse8 $l => [lreverse8 $l]" time {lreverse8 $l} 1 puts [time {lreverse8 $l} 10000] puts "testing _lreverse8 {} {*}$l => [_lreverse8 {} {*}$l]" time {_lreverse8 {} {*}$l} 1 puts [time {_lreverse8 {} {*}$l} 10000] : lreverse9 { Lars H: This is not fast, but it avoids index arithmetic. The idea can be nice in cases where you want to process the list elements while reversing their order. } proc lreverse9 {l} { set stack {} foreach item $l {set stack [list $stack $item]} set res {} while {[llength $stack]} { foreach {stack item} $stack break lappend res $item } return $res } puts "testing lreverse9 $l => [lreverse9 $l]" time {lreverse9 $l} 1 puts [time {lreverse9 $l} 10000] set l [lrepeat 800 a]; puts "longer list: 800 elements" puts "lreverse" time {lreverse $l} 1 puts [time {lreverse $l} 1000] puts "lreverse1" time {lreverse1 $l} 1 puts [time {lreverse1 $l} 1000] puts "lreverse2" time {lreverse2 $l} 1 puts [time {lreverse2 $l} 1000] puts "lreverse3" time {lreverse3 $l} 1 puts [time {lreverse3 $l} 1000] puts "lreverse4" time {lreverse4 $l} 1 puts [time {lreverse4 $l} 1000] puts "lreverse5" time {lreverse5 $l} 1 puts [time {lreverse5 $l} 1000] puts "lreverse6" time {lreverse6 $l} 1 puts [time {lreverse6 $l} 1000] puts "lreverse7" time {lreverse7 $l} 1 puts [time {lreverse7 $l} 1000] puts "lreverse8" time {lreverse8 $l} 1 puts [time {lreverse8 $l} 1000] puts "_lreverse8" time {_lreverse8 {} {*}$l} 1 puts [time {_lreverse8 {} {*}$l} 1000] puts "lreverse9" time {lreverse9 $l} 1 puts [time {lreverse9 $l} 1000] : {Consolidated timing results} { This list was redone 2014-03-09 on a Sony VAIO with an i3 2.40 GHz and 4GB RAM (3.67 usable), and ActiveState Tcl 8.6. small long lreverse comment list list implementation 1.49 5 builtin: obviously the fastest solution 2.20 91 lreverse1: countdown while loop with lappend 1.62 97 lreverse3: countdown for loop with lappend 2.36 184 lreverse6: foreach with lset (Tcl8.4) <- one [] 4.66 597 lreverse9: stack/unstack 3.36 2352 lreverse5: foreach with linsert <- two [] 4.07 2639 lreverse2: foreach with concat [list $e] $r <- three [] 5.01 4608 lreverse4: simple recursion 4.93 5176 lreverse7: tail recursion with lindex/lrange 5.24 7590 _lreverse8: tail recursion with {*} (Tcl8.5) 5.93 7592 lreverse8: tail recursion wrapper (*) (Tcl8.5) } {Timing results} { The following is the output of sourcing this file on my laptop, a Dell Latitude D630 Notebook with intel core duo and 2GB RAM, and Active State Tcl 8.5 } { testing builtin: lreverse 1 {2 3} {4 {5 6}} 7 => 7 {4 {5 6}} {2 3} 1 0.5942 microseconds per iteration testing lreverse1 1 {2 3} {4 {5 6}} 7 => 7 {4 {5 6}} {2 3} 1 1.8672 microseconds per iteration testing lreverse2 1 {2 3} {4 {5 6}} 7 => 7 {4 {5 6}} {2 3} 1 4.5811 microseconds per iteration testing lreverse3 1 {2 3} {4 {5 6}} 7 => 7 {4 {5 6}} {2 3} 1 1.8902 microseconds per iteration testing lreverse4 1 {2 3} {4 {5 6}} 7 => 7 {4 {5 6}} {2 3} 1 5.9768 microseconds per iteration testing lreverse5 1 {2 3} {4 {5 6}} 7 => 7 {4 {5 6}} {2 3} 1 3.4821 microseconds per iteration testing lreverse6 1 {2 3} {4 {5 6}} 7 => 7 {4 {5 6}} {2 3} 1 2.5686 microseconds per iteration testing lreverse7 1 {2 3} {4 {5 6}} 7 => 7 {4 {5 6}} {2 3} 1 6.3424 microseconds per iteration testing lreverse8 1 {2 3} {4 {5 6}} 7 => 7 {4 {5 6}} {2 3} 1 6.3327 microseconds per iteration testing _lreverse8 {} {*}1 {2 3} {4 {5 6}} 7 => 7 {4 {5 6}} {2 3} 1 5.629 microseconds per iteration longer list: 800 elements lreverse 6.204 microseconds per iteration lreverse1 116.202 microseconds per iteration lreverse2 924.386 microseconds per iteration lreverse3 118.412 microseconds per iteration lreverse4 3862.613 microseconds per iteration lreverse5 3255.545 microseconds per iteration lreverse6 244.969 microseconds per iteration lreverse7 7187.639 microseconds per iteration lreverse8 9097.354 microseconds per iteration _lreverse8 9084.144 microseconds per iteration }
AMG: [lreverse] can be used to invert a dict such that the keys and values exchange places.
This is not very efficient, since the dict has to be converted to a list representation before it can be reversed, then a new dict has to be created; however it is convenient. Often you have the data in a list representation to begin with, so in practice the performance might not be an issue.
Be careful with dicts that have duplicate values, since applying [lreverse] results in duplicate keys. The dict command discards duplicate keys, but normally it keeps the last instance of a duplicate. When using [lreverse] it instead keeps the first instance.
set map {a 1 b 1 c 2} set inv {1 a 1 b 2 c} dict get $map b ;# returns 1 dict get $inv 1 ;# returns b set inv [lreverse $map] ;# returns "2 c 1 b 1 a" dict get $map b ;# returns 1 dict get $inv 1 ;# returns a