Execute a Markov algorithm: Difference between revisions
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: <code> 00011H1111000 </code>
<br><br>
=={{header|11l}}==
{{trans|Nim}}
<lang 11l>T Rule
String pattern
String replacement
Bool terminating
F (pattern, replacement, terminating)
.pattern = pattern
.replacement = replacement
.terminating = terminating
F parse(rules)
[Rule] result
L(line) rules.split("\n")
I line.starts_with(‘#’)
L.continue
I line.trim(‘ ’).empty
L.continue
V (pat, rep) = line.split(‘ -> ’)
V terminating = 0B
I rep.starts_with(‘.’)
rep = rep[1..]
terminating = 1B
result.append(Rule(pat, rep, terminating))
R result
F apply(text, rules)
V result = text
V changed = 1B
L changed == 1B
changed = 0B
L(rule) rules
I rule.pattern C result
result = result.replace(rule.pattern, rule.replacement)
I rule.terminating
R result
changed = 1B
L.break
R result
V SampleTexts = [‘I bought a B of As from T S.’,
‘I bought a B of As from T S.’,
‘I bought a B of As W my Bgage from T S.’,
‘_1111*11111_’,
‘000000A000000’]
V RuleSets = [
‘# This rules file is extracted from Wikipedia:
# http://en.wikipedia.org/wiki/Markov_Algorithm
A -> apple
B -> bag
S -> shop
T -> the
the shop -> my brother
a never used -> .terminating rule’,
‘# Slightly modified from the rules on Wikipedia
A -> apple
B -> bag
S -> .shop
T -> the
the shop -> my brother
a never used -> .terminating rule’,
‘# BNF Syntax testing rules
A -> apple
WWWW -> with
Bgage -> ->.*
B -> bag
->.* -> money
W -> WW
S -> .shop
T -> the
the shop -> my brother
a never used -> .terminating rule’,
‘### Unary Multiplication Engine, for testing Markov Algorithm implementations
### By Donal Fellows.
# Unary addition engine
_+1 -> _1+
1+1 -> 11+
# Pass for converting from the splitting of multiplication into ordinary
# addition
1! -> !1
,! -> !+
_! -> _
# Unary multiplication by duplicating left side, right side times
1*1 -> x,@y
1x -> xX
X, -> 1,1
X1 -> 1X
_x -> _X
,x -> ,X
y1 -> 1y
y_ -> _
# Next phase of applying
1@1 -> x,@y
1@_ -> @_
,@_ -> !_
++ -> +
# Termination cleanup for addition
_1 -> 1
1+_ -> 1
_+_ -> ’,
‘# Turing machine: three-state busy beaver
#
# state A, symbol 0 => write 1, move right, new state B
A0 -> 1B
# state A, symbol 1 => write 1, move left, new state C
0A1 -> C01
1A1 -> C11
# state B, symbol 0 => write 1, move left, new state A
0B0 -> A01
1B0 -> A11
# state B, symbol 1 => write 1, move right, new state B
B1 -> 1B
# state C, symbol 0 => write 1, move left, new state B
0C0 -> B01
1C0 -> B11
# state C, symbol 1 => write 1, move left, halt
0C1 -> H01
1C1 -> H11’]
L(ruleset) RuleSets
V rules = parse(ruleset)
print(apply(SampleTexts[L.index], rules))</lang>
{{out}}
<pre>
I bought a bag of apples from my brother.
I bought a bag of apples from T shop.
I bought a bag of apples with my money from T shop.
11111111111111111111
00011H1111000
</pre>
=={{header|Ada}}==
|
Revision as of 00:44, 16 October 2021
This page uses content from Wikipedia. The original article was at Markov_algorithm. The list of authors can be seen in the page history. As with Rosetta Code, the text of Wikipedia is available under the GNU FDL. (See links for details on variance) |
You are encouraged to solve this task according to the task description, using any language you may know.
- Task
Create an interpreter for a Markov Algorithm.
Rules have the syntax:
<ruleset> ::= ((<comment> | <rule>) <newline>+)* <comment> ::= # {<any character>} <rule> ::= <pattern> <whitespace> -> <whitespace> [.] <replacement> <whitespace> ::= (<tab> | <space>) [<whitespace>]
There is one rule per line.
If there is a . (period) present before the <replacement>, then this is a terminating rule in which case the interpreter must halt execution.
A ruleset consists of a sequence of rules, with optional comments.
Rulesets
Use the following tests on entries:
- Ruleset 1
# This rules file is extracted from Wikipedia: # http://en.wikipedia.org/wiki/Markov_Algorithm A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule
Sample text of:
I bought a B of As from T S.
Should generate the output:
I bought a bag of apples from my brother.
- Ruleset 2
A test of the terminating rule
# Slightly modified from the rules on Wikipedia A -> apple B -> bag S -> .shop T -> the the shop -> my brother a never used -> .terminating rule
Sample text of:
I bought a B of As from T S.
Should generate:
I bought a bag of apples from T shop.
- Ruleset 3
This tests for correct substitution order and may trap simple regexp based replacement routines if special regexp characters are not escaped.
# BNF Syntax testing rules A -> apple WWWW -> with Bgage -> ->.* B -> bag ->.* -> money W -> WW S -> .shop T -> the the shop -> my brother a never used -> .terminating rule
Sample text of:
I bought a B of As W my Bgage from T S.
Should generate:
I bought a bag of apples with my money from T shop.
- Ruleset 4
This tests for correct order of scanning of rules, and may trap replacement routines that scan in the wrong order. It implements a general unary multiplication engine. (Note that the input expression must be placed within underscores in this implementation.)
### Unary Multiplication Engine, for testing Markov Algorithm implementations ### By Donal Fellows. # Unary addition engine _+1 -> _1+ 1+1 -> 11+ # Pass for converting from the splitting of multiplication into ordinary # addition 1! -> !1 ,! -> !+ _! -> _ # Unary multiplication by duplicating left side, right side times 1*1 -> x,@y 1x -> xX X, -> 1,1 X1 -> 1X _x -> _X ,x -> ,X y1 -> 1y y_ -> _ # Next phase of applying 1@1 -> x,@y 1@_ -> @_ ,@_ -> !_ ++ -> + # Termination cleanup for addition _1 -> 1 1+_ -> 1 _+_ ->
Sample text of:
_1111*11111_
should generate the output:
11111111111111111111
- Ruleset 5
A simple Turing machine, implementing a three-state busy beaver.
The tape consists of 0s and 1s, the states are A, B, C and H (for Halt), and the head position is indicated by writing the state letter before the character where the head is. All parts of the initial tape the machine operates on have to be given in the input.
Besides demonstrating that the Markov algorithm is Turing-complete, it also made me catch a bug in the C++ implementation which wasn't caught by the first four rulesets.
# Turing machine: three-state busy beaver # # state A, symbol 0 => write 1, move right, new state B A0 -> 1B # state A, symbol 1 => write 1, move left, new state C 0A1 -> C01 1A1 -> C11 # state B, symbol 0 => write 1, move left, new state A 0B0 -> A01 1B0 -> A11 # state B, symbol 1 => write 1, move right, new state B B1 -> 1B # state C, symbol 0 => write 1, move left, new state B 0C0 -> B01 1C0 -> B11 # state C, symbol 1 => write 1, move left, halt 0C1 -> H01 1C1 -> H11
This ruleset should turn
000000A000000
into
00011H1111000
11l
<lang 11l>T Rule
String pattern String replacement Bool terminating F (pattern, replacement, terminating) .pattern = pattern .replacement = replacement .terminating = terminating
F parse(rules)
[Rule] result L(line) rules.split("\n") I line.starts_with(‘#’) L.continue I line.trim(‘ ’).empty L.continue
V (pat, rep) = line.split(‘ -> ’)
V terminating = 0B I rep.starts_with(‘.’) rep = rep[1..] terminating = 1B
result.append(Rule(pat, rep, terminating)) R result
F apply(text, rules)
V result = text V changed = 1B
L changed == 1B changed = 0B L(rule) rules I rule.pattern C result result = result.replace(rule.pattern, rule.replacement) I rule.terminating R result changed = 1B L.break
R result
V SampleTexts = [‘I bought a B of As from T S.’,
‘I bought a B of As from T S.’, ‘I bought a B of As W my Bgage from T S.’, ‘_1111*11111_’, ‘000000A000000’]
V RuleSets = [ ‘# This rules file is extracted from Wikipedia:
A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule’,
‘# Slightly modified from the rules on Wikipedia A -> apple B -> bag S -> .shop T -> the the shop -> my brother a never used -> .terminating rule’,
‘# BNF Syntax testing rules A -> apple WWWW -> with Bgage -> ->.* B -> bag ->.* -> money W -> WW S -> .shop T -> the the shop -> my brother a never used -> .terminating rule’,
‘### Unary Multiplication Engine, for testing Markov Algorithm implementations
- By Donal Fellows.
- Unary addition engine
_+1 -> _1+ 1+1 -> 11+
- Pass for converting from the splitting of multiplication into ordinary
- addition
1! -> !1 ,! -> !+ _! -> _
- Unary multiplication by duplicating left side, right side times
1*1 -> x,@y 1x -> xX X, -> 1,1 X1 -> 1X _x -> _X ,x -> ,X y1 -> 1y y_ -> _
- Next phase of applying
1@1 -> x,@y 1@_ -> @_ ,@_ -> !_ ++ -> +
- Termination cleanup for addition
_1 -> 1 1+_ -> 1 _+_ -> ’,
‘# Turing machine: three-state busy beaver
- state A, symbol 0 => write 1, move right, new state B
A0 -> 1B
- state A, symbol 1 => write 1, move left, new state C
0A1 -> C01 1A1 -> C11
- state B, symbol 0 => write 1, move left, new state A
0B0 -> A01 1B0 -> A11
- state B, symbol 1 => write 1, move right, new state B
B1 -> 1B
- state C, symbol 0 => write 1, move left, new state B
0C0 -> B01 1C0 -> B11
- state C, symbol 1 => write 1, move left, halt
0C1 -> H01 1C1 -> H11’]
L(ruleset) RuleSets
V rules = parse(ruleset) print(apply(SampleTexts[L.index], rules))</lang>
- Output:
I bought a bag of apples from my brother. I bought a bag of apples from T shop. I bought a bag of apples with my money from T shop. 11111111111111111111 00011H1111000
Ada
markov.ads: <lang Ada>with Ada.Strings.Unbounded;
package Markov is
use Ada.Strings.Unbounded; type Ruleset (Length : Natural) is private; type String_Array is array (Positive range <>) of Unbounded_String; function Parse (S : String_Array) return Ruleset; function Apply (R : Ruleset; S : String) return String;
private
type Entry_Kind is (Comment, Rule); type Set_Entry (Kind : Entry_Kind := Rule) is record case Kind is when Rule => Source : Unbounded_String; Target : Unbounded_String; Is_Terminating : Boolean; when Comment => Text : Unbounded_String; end case; end record; subtype Rule_Entry is Set_Entry (Kind => Rule); type Entry_Array is array (Positive range <>) of Set_Entry; type Ruleset (Length : Natural) is record Entries : Entry_Array (1 .. Length); end record;
end Markov;</lang>
markov.adb: <lang Ada>package body Markov is
function Parse (S : String_Array) return Ruleset is Result : Ruleset (Length => S'Length); begin for I in S'Range loop if Length (S (I)) = 0 or else Element (S (I), 1) = '#' then Result.Entries (I) := (Kind => Comment, Text => S (I)); else declare Separator : Natural; Terminating : Boolean; Target : Unbounded_String; begin Separator := Index (S (I), " -> "); if Separator = 0 then raise Constraint_Error; end if; Target := Unbounded_Slice (Source => S (I), Low => Separator + 4, High => Length (S (I))); Terminating := Length (Target) > 0 and then Element (Target, 1) = '.'; if Terminating then Delete (Source => Target, From => 1, Through => 1); end if; Result.Entries (I) := (Kind => Rule, Source => Unbounded_Slice (Source => S (I), Low => 1, High => Separator - 1), Target => Target, Is_Terminating => Terminating); end; end if; end loop; return Result; end Parse;
procedure Apply (R : Rule_Entry; S : in out Unbounded_String; Modified : in out Boolean) is Pattern : String := To_String (R.Source); Where : Natural := Index (S, Pattern); begin while Where /= 0 loop Modified := True; Replace_Slice (Source => S, Low => Where, High => Where + Pattern'Length - 1, By => To_String (R.Target)); Where := Index (S, Pattern, Where + Length (R.Target)); end loop; end Apply;
function Apply (R : Ruleset; S : String) return String is Result : Unbounded_String := To_Unbounded_String (S); Current_Rule : Set_Entry; Modified : Boolean := False; begin loop Modified := False; for I in R.Entries'Range loop Current_Rule := R.Entries (I); if Current_Rule.Kind = Rule then Apply (Current_Rule, Result, Modified); exit when Current_Rule.Is_Terminating or else Modified; end if; end loop; exit when not Modified; end loop; return To_String (Result); end Apply;
end Markov;</lang>
test_markov.adb: <lang Ada>with Ada.Command_Line; with Ada.Text_IO.Unbounded_IO; with Ada.Strings.Unbounded; with Markov;
procedure Test_Markov is
use Ada.Strings.Unbounded; package IO renames Ada.Text_IO.Unbounded_IO; Rule_File : Ada.Text_IO.File_Type; Line_Count : Natural := 0;
begin
if Ada.Command_Line.Argument_Count /= 2 then Ada.Text_IO.Put_Line ("Usage: test_markov ruleset_file source_file"); return; end if; Ada.Text_IO.Open (File => Rule_File, Mode => Ada.Text_IO.In_File, Name => Ada.Command_Line.Argument (1)); while not Ada.Text_IO.End_Of_File (Rule_File) loop Ada.Text_IO.Skip_Line (Rule_File); Line_Count := Line_Count + 1; end loop; declare Lines : Markov.String_Array (1 .. Line_Count); begin Ada.Text_IO.Reset (Rule_File); for I in Lines'Range loop Lines (I) := IO.Get_Line (Rule_File); end loop; Ada.Text_IO.Close (Rule_File);
declare Ruleset : Markov.Ruleset := Markov.Parse (Lines); Source_File : Ada.Text_IO.File_Type; begin Ada.Text_IO.Open (File => Source_File, Mode => Ada.Text_IO.In_File, Name => Ada.Command_Line.Argument (2)); while not Ada.Text_IO.End_Of_File (Source_File) loop Ada.Text_IO.Put_Line (Markov.Apply (Ruleset, Ada.Text_IO.Get_Line (Source_File))); end loop; Ada.Text_IO.Close (Source_File); end; end;
end Test_Markov;</lang>
Output (rulesX contains the ruleset of above examples and testX the example text):
$ ./test_markov rules1 test1 I bought a bag of apples from my brother. $ ./test_markov rules2 test2 I bought a bag of apples from T shop. $ ./test_markov rules3 test3 I bought a bag of apples with my money from T shop. $ ./test_markov rules4 test4 11111111111111111111 $ ./test_markov rules5 test5 00011H1111000
APL
<lang APL>markov←{
trim←{(~(∧\∨⌽∘(∧\)∘⌽)⍵∊⎕UCS 9 32)/⍵} rules←(~rules∊⎕UCS 10 13)⊆rules←80 ¯1 ⎕MAP ⍺ rules←('#'≠⊃¨rules)/rules rules←{ norm←' '@(9=⎕UCS)⊢⍵ spos←⍸' -> '⍷norm pat←trim spos↑⍵ repl←trim(spos+2)↓⍵ term←'.'=⊃repl term pat(term↓repl) }¨rules apply←{ 0=⍴rule←⍸∨/¨(2⊃¨⍺)⍷¨⊂⍵:⍵ term pat repl←⊃⍺[⊃rule] idx←(⊃⍸pat⍷⍵)-1 ⍺ ∇⍣(~term)⊢(idx↑⍵),repl,(idx+≢pat)↓⍵ } rules apply ⍵
}</lang>
- Output:
'f:\ruleset1.mkv' markov 'I bought a B of As from T S.' I bought a bag of apples from my brother. 'f:\ruleset2.mkv' markov 'I bought a B of As from T S.' I bought a bag of apples from T shop. 'f:\ruleset3.mkv' markov 'I bought a B of As W my Bgage from T S.' I bought a bag of apples with my money from T shop. 'f:\ruleset4.mkv' markov '_1111*11111_' 11111111111111111111 'f:\ruleset5.mkv' markov '000000A000000' 00011H1111000
AutoHotkey
<lang autohotkey>;---------------------------------------------------------------------------
- Markov Algorithm.ahk
- by wolf_II
- ---------------------------------------------------------------------------
- interpreter for a Markov Algorithm
- ---------------------------------------------------------------------------
- ---------------------------------------------------------------------------
AutoExecute: ; auto-execute section of the script
- ---------------------------------------------------------------------------
#SingleInstance, Force ; only one instance allowed #NoEnv ; don't check empty variables StartupDir := A_WorkingDir ; remember startup directory SetWorkingDir, %A_ScriptDir% ; change directoy StringCaseSense, On ; case sensitive comparisons ;----------------------------------------------------------------------- AppName := "Markov Algorithm" Gosub, GuiCreate Gui, Show,, %AppName%
Return
- ---------------------------------------------------------------------------
GuiCreate: ; create the GUI
- ---------------------------------------------------------------------------
; GUI options Gui, -MinimizeBox Gui, Add, Edit, y0 h0 ; catch the focus
; Ruleset Gui, Add, GroupBox, w445 h145 Section, Ruleset Gui, Add, Edit, xs+15 ys+20 w300 r8 vRuleset Gui, Add, Button, x+15 w100, Load Ruleset Gui, Add, Button, wp, Save Ruleset Gui, Add, Button, w30, 1 Gui, Add, Button, x+5 wp, 2 Gui, Add, Button, x+5 wp, 3 Gui, Add, Button, xs+330 y+6 wp, 4 Gui, Add, Button, x+5 wp, 5
; String Gui, Add, GroupBox, xs w445 h75 Section, String Gui, Add, Edit, xs+15 ys+20 w300 vString Gui, Add, Button, x+15 w100, Apply Ruleset Gui, Add, Button, xp wp Hidden, Stop Gui, Add, CheckBox, xs+15 yp+30 vSingleStepping, Single Stepping?
; Output Gui, Add, GroupBox, xs w445 h235 Section, Output Gui, Add, Edit, xs+15 ys+20 w415 r15 ReadOnly vOutput HwndhOut
Return
- ---------------------------------------------------------------------------
GuiClose:
- ---------------------------------------------------------------------------
ExitApp
Return
- ---------------------------------------------------------------------------
ButtonLoadRuleset: ; load ruleset from file
- ---------------------------------------------------------------------------
Gui, +OwnDialogs FileSelectFile, RulesetFile,,, Load Ruleset, *.markov If Not SubStr(RulesetFile, -6) = ".markov" RulesetFile .= ".markov" If FileExist(RulesetFile) { FileRead, Ruleset, %RulesetFile% GuiControl,, Ruleset, %Ruleset% } Else MsgBox, 16, Error - %AppName%, File not found:`n`n"%RulesetFile%"
Return
- ---------------------------------------------------------------------------
ButtonSaveRuleset: ; save ruleset to file
- ---------------------------------------------------------------------------
Gui, +OwnDialogs Gui, Submit, NoHide FileSelectFile, RulesetFile, S16,, Save Ruleset, *.markov If Not SubStr(RulesetFile, -6) = ".markov" RulesetFile .= ".markov" FileDelete, %RulesetFile% FileAppend, %Ruleset%, %RulesetFile% Gui, Show
Return
_
- ---------------------------------------------------------------------------
Button1: ; http://rosettacode.org/wiki/Execute_a_Markov_algorithm#Ruleset_1
- ---------------------------------------------------------------------------
GuiControl,, Output ; clear output GuiControl,, String, I bought a B of As from T S. GuiControl,, Ruleset, (LTrim # This rules file is extracted from Wikipedia: # http://en.wikipedia.org/wiki/Markov_Algorithm A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule )
Return
- ---------------------------------------------------------------------------
Button2: ; http://rosettacode.org/wiki/Execute_a_Markov_algorithm#Ruleset_2
- ---------------------------------------------------------------------------
GuiControl,, Output ; clear output GuiControl,, String, I bought a B of As from T S. GuiControl,, Ruleset, (LTrim # Slightly modified from the rules on Wikipedia A -> apple B -> bag S -> .shop T -> the the shop -> my brother a never used -> .terminating rule )
Return
- ---------------------------------------------------------------------------
Button3: ; http://rosettacode.org/wiki/Execute_a_Markov_algorithm#Ruleset_3
- ---------------------------------------------------------------------------
GuiControl,, Output ; clear output GuiControl,, String, I bought a B of As W my Bgage from T S. GuiControl,, Ruleset, (LTrim # BNF Syntax testing rules A -> apple WWWW -> with Bgage -> ->.* B -> bag ->.* -> money W -> WW S -> .shop T -> the the shop -> my brother a never used -> .terminating rule )
Return
- ---------------------------------------------------------------------------
Button4: ; http://rosettacode.org/wiki/Execute_a_Markov_algorithm#Ruleset_4
- ---------------------------------------------------------------------------
GuiControl,, Output ; clear output GuiControl,, String, _1111*11111_ GuiControl,, Ruleset, (LTrim ### Unary Multiplication Engine, for testing Markov Algorithm implementations ### By Donal Fellows. # Unary addition engine _+1 -> _1+ 1+1 -> 11+ # Pass for converting from the splitting of multiplication into ordinary # addition 1! -> !1 ,! -> !+ _! -> _ # Unary multiplication by duplicating left side, right side times 1*1 -> x,@y 1x -> xX X, -> 1,1 X1 -> 1X _x -> _X ,x -> ,X y1 -> 1y y_ -> _ # Next phase of applying 1@1 -> x,@y 1@_ -> @_ ,@_ -> !_ ++ -> + # Termination cleanup for addition _1 -> 1 1+_ -> 1 _+_ -> )
Return
- ---------------------------------------------------------------------------
Button5: ; http://rosettacode.org/wiki/Execute_a_Markov_algorithm#Ruleset_5
- ---------------------------------------------------------------------------
GuiControl,, Output ; clear output GuiControl,, String, 000000A000000 GuiControl,, Ruleset, (LTrim # Turing machine: three-state busy beaver # # state A, symbol 0 => write 1, move right, new state B A0 -> 1B # state A, symbol 1 => write 1, move left, new state C 0A1 -> C01 1A1 -> C11 # state B, symbol 0 => write 1, move left, new state A 0B0 -> A01 1B0 -> A11 # state B, symbol 1 => write 1, move right, new state B B1 -> 1B # state C, symbol 0 => write 1, move left, new state B 0C0 -> B01 1C0 -> B11 # state C, symbol 1 => write 1, move left, halt 0C1 -> H01 1C1 -> H11 )
Return
- ---------------------------------------------------------------------------
ButtonApplyRuleset: ; flow control for Algorithm
- ---------------------------------------------------------------------------
; prepare Gui, Submit, NoHide GuiControl,, Output ; clear Controls(False) ; disable Count := 0 Subst := True Stop := False
; keep substituting for as long as necessary While, Subst { Subst := False ; reset control variable IfEqual, Stop, 1, Break Gosub, Algorithm }
; clean up Output("Substitution count: " Count) Controls(True) ; re-enable
Return
- ---------------------------------------------------------------------------
ButtonStop: ; this button is initially hidden
- ---------------------------------------------------------------------------
Stop := True
Return
- ---------------------------------------------------------------------------
Algorithm: ; http://rosettacode.org/wiki/Execute_a_Markov_algorithm
- ---------------------------------------------------------------------------
; Parse the ruleset and apply each rule to the string. Whenever a rule ; has changed the string goto first rule. Continue until a encountering ; a terminating rule, or until no further changes to the strings are ; made. ;----------------------------------------------------------------------- Loop, Parse, Ruleset, `n, `r ; always start from the beginning { ; check for comment If SubStr(A_LoopField, 1, 1) = "#" Continue ; get next line
; split a rule into $Search, $Terminator and $Replace LookFor := "(?P<Search>.+) -> (?P<Terminator>\.?)(?P<Replace>.+)" RegExMatch(A_LoopField, LookFor, $)
; single stepping through possible substitutions If SingleStepping MsgBox,, %AppName%, % "" . "Rule = """ A_LoopField """`n`n" . "Search`t= """ $Search """`n" . "Replace`t= """ $Replace """`n" . "Termintor`t= """ ($Terminator ? "True" : "False") """`n"
; try to substitute StringReplace, String, String, %$Search%, %$Replace%, UseErrorLevel
; any success? If ErrorLevel { ; yes, substitution done Count++ ; keep count Subst := True ; set control variable Output(String) ; write new string to output }
; terminate? If $Terminator { ; yes, terminate Stop := True ; set control variable Break ; back to flow control }
; we are not yet terminated ... If Subst ; but we just did a substitution Break ; back to flow control }
Return
- ---------------------------------------------------------------------------
Controls(Bool) { ; [en|dis]able controls
- ---------------------------------------------------------------------------
Enable := Bool ? "+" : "-" Disable := Bool ? "-" : "+" Loop, 2 GuiControl, %Disable%ReadOnly, % "Edit" A_Index + 1 Loop, 7 GuiControl, %Disable%Disabled, % "Button" A_Index + 1 GuiControl, %Disable%Disabled, Edit4 GuiControl, %Disable%Hidden, Button10 GuiControl, %Enable%Hidden, Button11 GuiControl, %Disable%Disabled, Button12
}
- ---------------------------------------------------------------------------
Output(Text) { ; append text to output
- ---------------------------------------------------------------------------
static EM_REPLACESEL = 0xC2 global hOut Sleep, 100 Text .= "`r`n" SendMessage, EM_REPLACESEL,, &Text,, ahk_id %hOut%
}
- ---------- end of file ----------------------------------------------------</lang>
BBC BASIC
<lang bbcbasic> PRINT FNmarkov("ruleset1.txt", "I bought a B of As from T S.")
PRINT FNmarkov("ruleset2.txt", "I bought a B of As from T S.") PRINT FNmarkov("ruleset3.txt", "I bought a B of As W my Bgage from T S.") PRINT FNmarkov("ruleset4.txt", "_1111*11111_") PRINT FNmarkov("ruleset5.txt", "000000A000000") END DEF FNmarkov(rulefile$, text$) LOCAL i%, done%, rules%, rule$, old$, new$ rules% = OPENIN(rulefile$) IF rules%=0 ERROR 100, "Cannot open rules file" REPEAT rule$ = GET$#rules% IF ASC(rule$)<>35 THEN REPEAT i% = INSTR(rule$, CHR$(9)) IF i% MID$(rule$,i%,1) = " " UNTIL i%=0 i% = INSTR(rule$, " -> ") IF i% THEN old$ = LEFT$(rule$,i%-1) WHILE RIGHT$(old$)=" " old$ = LEFT$(old$) : ENDWHILE new$ = MID$(rule$,i%+4) WHILE ASC(new$)=32 new$ = MID$(new$,2) : ENDWHILE IF ASC(new$)=46 new$ = MID$(new$,2) : done% = TRUE i% = INSTR(text$,old$) IF i% THEN text$ = LEFT$(text$,i%-1) + new$ + MID$(text$,i%+LEN(old$)) PTR#rules% = 0 ENDIF ENDIF ENDIF UNTIL EOF#rules% OR done% CLOSE #rules% = text$</lang>
Output:
I bought a bag of apples from my brother. I bought a bag of apples from T shop. I bought a bag of apples with my money from T shop. 11111111111111111111 00011H1111000
Bracmat
Save the following text to a file "markov.bra": <lang bracmat> markov= { First the patterns that describe the rules syntax. This is a naive and not very efficient way to parse the rules, but it closely matches the problem description, which is nice. }
( ruleset = >%@" " ? { Added: assume that a rule cannot start with whitespace. The %@ say that the thing to match must be exactly one byte. % means 'one or more'. @ means 'zero or one'. } : ((!comment|!rule) !newlines) !ruleset | { Recursion terminates here: match empty string. } ) & (comment="#" ?com) & ( rule = %?pattern !whitespace "->" !whitespace ( "." %?replacement&stop:?stop | %?replacement ) ) & ( whitespace = (\t|" ") (!whitespace|) ) & ( newlines = ( (\n|\r) & ( :!pattern:!replacement {Do nothing. We matched an empty line.} | (!pattern.!replacement.!stop) !rules:?rules { Add pattern, replacement and the stop (empty string or "stop") to a list of triplets. This list will contain the rules in reverse order. Then, reset these variables, so they are not added once more if an empty line follows. } & :?stop:?pattern:?replacement ) ) (!newlines|) )
{ Compile the textual rules to a single Bracmat pattern. }
& ( compileRules = stop pattern replacement rules,pat rep stp . :?stop:?pattern:?replacement:?rules { Important! Initialise these variables. } & @(!arg:!ruleset) { That's all. The textual rules are parsed and converted to a list of triplets. The rules in the list are in reversed order. } & !rules:(?pat.?rep.?stp) ?rules { The head of the list is the last rule. Use it to initialise the pattern "ruleSetAsPattern". The single quote introduces a macro substition. All symbols preceded with a $ are substituted. } & ' ( ?A ()$pat ?Z & $stp:?stop & $rep:?replacement ) : (=?ruleSetAsPattern) { Add all remaining rules as new subpatterns to "ruleSetAsPattern". Separate with the OR symbol. } & whl ' ( !rules:(?pat.?rep.?stp) ?rules & ' ( ?A ()$pat ?Z & $stp:?stop & $rep:?replacement | $ruleSetAsPattern ) : (=?ruleSetAsPattern) ) & '$ruleSetAsPattern ) { Function that takes two arguments: a rule set (as text) and a subject string. The function returns the transformed string. } & ( applyRules = rulesSetAsText subject ruleSetAsPattern , A Z replacement stop . !arg:(?rulesSetAsText.?subject) & compileRules$!rulesSetAsText:(=?ruleSetAsPattern) { Apply rule until no match or until variable "stop" has been set to the value "stop". } & whl ' ( @(!subject:!ruleSetAsPattern) & str$(!A !replacement !Z):?subject & !stop:~stop ) & !subject )
{ Tests: }
& out $ ( applyRules $ ( "# This rules file is extracted from Wikipedia:
A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule "
. "I bought a B of As from T S." ) ) & out $ ( applyRules $ ( "# Slightly modified from the rules on Wikipedia
A -> apple B -> bag S -> .shop T -> the the shop -> my brother a never used -> .terminating rule "
. "I bought a B of As from T S." ) ) & out $ ( applyRules $ ( "# BNF Syntax testing rules
A -> apple WWWW -> with Bgage -> ->.* B -> bag ->.* -> money W -> WW S -> .shop T -> the the shop -> my brother a never used -> .terminating rule "
. "I bought a B of As W my Bgage from T S." ) ) & out $ ( applyRules $ ( "### Unary Multiplication Engine, for testing Markov Algorithm implementations
- By Donal Fellows.
- Unary addition engine
_+1 -> _1+ 1+1 -> 11+
- Pass for converting from the splitting of multiplication into ordinary
- addition
1! -> !1 ,! -> !+ _! -> _
- Unary multiplication by duplicating left side, right side times
1*1 -> x,@y 1x -> xX X, -> 1,1 X1 -> 1X _x -> _X ,x -> ,X y1 -> 1y y_ -> _
- Next phase of applying
1@1 -> x,@y 1@_ -> @_ ,@_ -> !_ ++ -> +
- Termination cleanup for addition
_1 -> 1 1+_ -> 1 _+_ -> "
. "_1111*11111_" ) ) & out $ ( applyRules $ ( "# Turing machine: three-state busy beaver
- state A, symbol 0 => write 1, move right, new state B
A0 -> 1B
- state A, symbol 1 => write 1, move left, new state C
0A1 -> C01 1A1 -> C11
- state B, symbol 0 => write 1, move left, new state A
0B0 -> A01 1B0 -> A11
- state B, symbol 1 => write 1, move right, new state B
B1 -> 1B
- state C, symbol 0 => write 1, move left, new state B
0C0 -> B01 1C0 -> B11
- state C, symbol 1 => write 1, move left, halt
0C1 -> H01 1C1 -> H11 "
. 000000A000000 ) ) & ok
| failure; </lang>
Test:
{?} get$"markov.bra" {!} markov S 0,01 sec {?} !markov I bought a bag of apples from my brother. I bought a bag of apples from T shop. I bought a bag of apples with my money from T shop. 11111111111111111111 00011H1111000 {!} ok S 0,41 sec
C
<lang c>#include <stdio.h>
- include <stdlib.h>
- include <string.h>
- include <unistd.h>
- include <fcntl.h>
- include <sys/types.h>
- include <sys/stat.h>
- include <ctype.h>
typedef struct { char * s; size_t alloc_len; } string;
typedef struct {
char *pat, *repl; int terminate;
} rule_t;
typedef struct {
int n; rule_t *rules; char *buf;
} ruleset_t;
void ruleset_del(ruleset_t *r) {
if (r->rules) free(r->rules); if (r->buf) free(r->buf); free(r);
}
string * str_new(const char *s) {
int l = strlen(s); string *str = malloc(sizeof(string)); str->s = malloc(l + 1); strcpy(str->s, s); str->alloc_len = l + 1; return str;
}
void str_append(string *str, const char *s, int len) {
int l = strlen(str->s); if (len == -1) len = strlen(s);
if (str->alloc_len < l + len + 1) { str->alloc_len = l + len + 1; str->s = realloc(str->s, str->alloc_len); } memcpy(str->s + l, s, len); str->s[l + len] = '\0';
}
/* swap content of dest and src, and truncate src string */ void str_transfer(string *dest, string *src) {
size_t tlen = dest->alloc_len; dest->alloc_len = src->alloc_len; src->alloc_len = tlen;
char *ts = dest->s; dest->s = src->s; src->s = ts; src->s[0] = '\0';
}
void str_del(string *s) {
if (s->s) free(s->s); free(s);
}
void str_markov(string *str, ruleset_t *r) {
int i, j, sl, pl; int changed = 0, done = 0; string *tmp = str_new("");
while (!done) { changed = 0; for (i = 0; !done && !changed && i < r->n; i++) { pl = strlen(r->rules[i].pat); sl = strlen(str->s); for (j = 0; j < sl; j++) { if (strncmp(str->s + j, r->rules[i].pat, pl)) continue; str_append(tmp, str->s, j); str_append(tmp, r->rules[i].repl, -1); str_append(tmp, str->s + j + pl, -1);
str_transfer(str, tmp); changed = 1;
if (r->rules[i].terminate) done = 1; break; } } if (!changed) break; } str_del(tmp); return;
}
ruleset_t* read_rules(const char *name) {
struct stat s; char *buf; size_t i, j, k, tmp; rule_t *rules = 0; int n = 0; /* number of rules */
int fd = open(name, O_RDONLY); if (fd == -1) return 0;
fstat(fd, &s); buf = malloc(s.st_size + 2); read(fd, buf, s.st_size); buf[s.st_size] = '\n'; buf[s.st_size + 1] = '\0'; close(fd);
for (i = j = 0; buf[i] != '\0'; i++) { if (buf[i] != '\n') continue;
/* skip comments */ if (buf[j] == '#' || i == j) { j = i + 1; continue; }
/* find the '->' */ for (k = j + 1; k < i - 3; k++) if (isspace(buf[k]) && !strncmp(buf + k + 1, "->", 2)) break;
if (k >= i - 3) { printf("parse error: no -> in %.*s\n", i - j, buf + j); break; }
/* left side: backtrack through whitespaces */ for (tmp = k; tmp > j && isspace(buf[--tmp]); ); if (tmp < j) { printf("left side blank? %.*s\n", i - j, buf + j); break; } buf[++tmp] = '\0';
/* right side */ for (k += 3; k < i && isspace(buf[++k]);); buf[i] = '\0';
rules = realloc(rules, sizeof(rule_t) * (1 + n)); rules[n].pat = buf + j;
if (buf[k] == '.') { rules[n].terminate = 1; rules[n].repl = buf + k + 1; } else { rules[n].terminate = 0; rules[n].repl = buf + k; } n++;
j = i + 1; }
ruleset_t *r = malloc(sizeof(ruleset_t)); r->buf = buf; r->rules = rules; r->n = n; return r;
}
int test_rules(const char *s, const char *file) {
ruleset_t * r = read_rules(file); if (!r) return 0; printf("Rules from '%s' ok\n", file);
string *ss = str_new(s); printf("text: %s\n", ss->s);
str_markov(ss, r); printf("markoved: %s\n", ss->s);
str_del(ss); ruleset_del(r);
return printf("\n");
}
int main() {
/* rule 1-5 are files containing rules from page top */ test_rules("I bought a B of As from T S.", "rule1"); test_rules("I bought a B of As from T S.", "rule2"); test_rules("I bought a B of As W my Bgage from T S.", "rule3"); test_rules("_1111*11111_", "rule4"); test_rules("000000A000000", "rule5");
return 0;
}</lang>output<lang>Rules from 'rule1' ok text: I bought a B of As from T S. markoved: I bought a bag of apples from my brother.
Rules from 'rule2' ok text: I bought a B of As from T S. markoved: I bought a bag of apples from T shop.
Rules from 'rule3' ok text: I bought a B of As W my Bgage from T S. markoved: I bought a bag of apples with my money from T shop.
Rules from 'rule4' ok text: _1111*11111_ markoved: 11111111111111111111
Rules from 'rule5' ok text: 000000A000000 markoved: 00011H1111000 </lang>
C++
Note: Non-use of iswhite
is intentional, since depending on the locale, other chars besides space and tab might be detected by that function.
<lang cpp>
- include <cstdlib>
- include <iostream>
- include <fstream>
- include <vector>
- include <string>
struct rule {
std::string pattern; std::string replacement; bool terminal; rule(std::string pat, std::string rep, bool term): pattern(pat), replacement(rep), terminal(term) { }
};
std::string const whitespace = " \t"; std::string::size_type const npos = std::string::npos;
bool is_whitespace(char c) {
return whitespace.find(c) != npos;
}
std::vector<rule> read_rules(std::ifstream& rulefile) {
std::vector<rule> rules; std::string line; while (std::getline(rulefile, line)) { std::string::size_type pos; // remove comments pos = line.find('#'); if (pos != npos) line.resize(pos); // ignore lines consisting only of whitespace if (line.find_first_not_of(whitespace) == npos) continue; // find "->" surrounded by whitespace pos = line.find("->"); while (pos != npos && (pos == 0 || !is_whitespace(line[pos-1]))) pos = line.find("->", pos+1); if (pos == npos || line.length() < pos+3 || !is_whitespace(line[pos+2])) { std::cerr << "invalid rule: " << line << "\n"; std::exit(EXIT_FAILURE); } std::string pattern = line.substr(0, pos-1); std::string replacement = line.substr(pos+3); // remove additional separating whitespace pattern.erase(pattern.find_last_not_of(whitespace)+1); replacement.erase(0, replacement.find_first_not_of(whitespace)); // test for terminal rule bool terminal = !replacement.empty() && replacement[0] == '.'; if (terminal) replacement.erase(0,1); rules.push_back(rule(pattern, replacement, terminal)); }
return rules;
}
std::string markov(std::vector<rule> rules, std::string input) {
std::string& output = input; std::vector<rule>::iterator iter = rules.begin();
// Loop through each rule, transforming our current version // with each rule. while (iter != rules.end()) { std::string::size_type pos = output.find(iter->pattern); if (pos != npos) { output.replace(pos, iter->pattern.length(), iter->replacement); if (iter->terminal) break; iter = rules.begin(); } else ++iter; }
return output;
}
int main(int argc, char* argv[]) {
if (argc != 3) { std::cout << "usage:\n " << argv[0] << " rulefile text\n"; return EXIT_FAILURE; } std::ifstream rulefile(argv[1]); std::vector<rule> rules = read_rules(rulefile);
std::string input(argv[2]); std::string output = markov(rules, input);
std::cout << output << "\n";
}</lang>
Common Lisp
I should mention that this uses the regular expression machinery present in Allegro Lisp but not Common Lisp generally (though there are public domain Lisp libraries). <lang lisp>;;; Keeps track of all our rules (defclass markov ()
((rules :initarg :rules :initform nil :accessor rules)))
- Definition of a rule
(defclass rule ()
((pattern :initarg :pattern :accessor pattern) (replacement :initarg :replacement :accessor replacement) (terminal :initform nil :initarg :terminal :accessor terminal)))
- Parse a rule with this regular expression
(defparameter *rex->* (compile-re "^(.+)(?: |\\t)->(?: |\\t)(\\.?)(.*)$"))
- Create a rule and add it to the markov object
(defmethod update-markov ((mkv markov) lhs terminating rhs)
(setf (rules mkv) (cons (make-instance 'rule :pattern lhs :replacement rhs :terminal terminating) (rules mkv))))
- Parse a line and add it to the markov object
(defmethod parse-line ((mkv markov) line)
(let ((trimmed (string-trim #(#\Space #\Tab) line))) (if (not (or (eql #\# (aref trimmed 0)) (equal "" trimmed))) (let ((vals (multiple-value-list (match-re *rex->* line)))) (if (not (car vals)) (progn (format t "syntax error in ~A" line) (throw 'fail t))) (update-markov mkv (nth 2 vals) (equal "." (nth 3 vals)) (nth 4 vals))))))
- Make a markov object from the string of rules
(defun make-markov (rules-text)
(catch 'fail (let ((mkv (make-instance 'markov))) (with-input-from-string (s rules-text) (loop for line = (read-line s nil) while line do (parse-line mkv line))) (setf (rules mkv) (reverse (rules mkv))) mkv)))
- Given a rule and bounds where it applies, apply it to the input text
(defun adjust (rule-info text)
(let* ((rule (car rule-info)) (index-start (cadr rule-info)) (index-end (caddr rule-info)) (prefix (subseq text 0 index-start)) (suffix (subseq text index-end)) (replace (replacement rule))) (concatenate 'string prefix replace suffix)))
- Get the next applicable rule or nil if none
(defmethod get-rule ((markov markov) text)
(dolist (rule (rules markov) nil) (let ((index (search (pattern rule) text))) (if index (return (list rule index (+ index (length (pattern rule)))))))))
- Interpret text using a markov object
(defmethod interpret ((markov markov) text)
(let ((rule-info (get-rule markov text)) (ret text)) (loop (if (not rule-info) (return ret)) (setf ret (adjust rule-info ret)) (if (terminal (car rule-info)) (return ret)) (setf rule-info (get-rule markov ret)))))</lang>
Testing: <lang>(defparameter
*rules1*
"# This rules file is extracted from Wikipedia:
A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule")
- Lots of other defparameters for rules omitted here...
(defun test ()
(format t "~A~%" (interpret (make-markov *rules1*) "I bought a B of As from T S.")) (format t "~A~%" (interpret (make-markov *rules2*) "I bought a B of As from T S.")) (format t "~A~%" (interpret (make-markov *rules3*) "I bought a B of As W my Bgage from T S.")) (format t "~A~%" (interpret (make-markov *rules4*) "_1111*11111_")) (format t "~A~%" (interpret (make-markov *rules5*) "000000A000000")) )
(test) I bought a bag of apples from my brother. I bought a bag of apples from T shop. I bought a bag of apples with my money from T shop. 11111111111111111111 00011H1111000 NIL </lang>
Cowgol
<lang cowgol>include "cowgol.coh"; include "strings.coh"; include "malloc.coh"; include "argv.coh"; include "file.coh";
record Rule is
pattern: [uint8]; replacement: [uint8]; next: [Rule]; terminates: uint8;
end record;
sub AllocRule(): (rule: [Rule]) is
rule := Alloc(@bytesof Rule) as [Rule]; MemZero(rule as [uint8], @bytesof Rule);
end sub;
sub ParseRule(text: [uint8]): (rule: [Rule]) is
sub ParseError() is print("Failed to parse rule: "); print(text); print_nl(); ExitWithError(); end sub; var cur := text; sub SkipWs() is while [cur] != 0 and [cur] <= ' ' loop cur := @next cur; end loop; end sub; sub AllocAndCopy(src: [uint8], length: intptr): (copy: [uint8]) is copy := Alloc(length + 1); MemCopy(src, length, copy); [copy + length] := 0; end sub; SkipWs(); if [cur] == '#' or [cur] == 0 then # comment or empty line rule := 0 as [Rule]; return; end if; var patternStart := cur;
# find the " ->" while [cur] != 0 and ([cur] > ' ' or [cur+1] != '-' or [cur+2] != '>') loop cur := @next cur; end loop; if [cur] == 0 then ParseError(); end if;
# find last char of pattern var patternEnd := cur; while patternStart < patternEnd and [patternEnd] <= ' ' loop patternEnd := @prev patternEnd; end loop;
cur := cur + 3; # whitespace + '->' SkipWs(); var replacementStart := cur;
# find last char of replacement while [cur] != 0 loop cur := @next cur; end loop; while replacementStart < cur and [cur] <= ' ' loop cur := @prev cur; end loop;
# make rule object rule := AllocRule(); rule.pattern := AllocAndCopy(patternStart, patternEnd-patternStart+1); if [replacementStart] == '.' then rule.terminates := 1; replacementStart := @next replacementStart; end if; rule.replacement := AllocAndCopy(replacementStart, cur-replacementStart+1);
end sub;
sub FindMatch(needle: [uint8], haystack: [uint8]): (match: [uint8]) is
match := 0 as [uint8]; while [haystack] != 0 loop var n := needle; var h := haystack; while [n] != 0 and [h] != 0 and [n] == [h] loop n := @next n; h := @next h; end loop; if [n] == 0 then match := haystack; return; end if; haystack := @next haystack; end loop;
end sub;
const NO_MATCH := 0; const HALT := 1; const CONTINUE := 2; sub ApplyRule(rule: [Rule], in: [uint8], out: [uint8]): (result: uint8) is
var match := FindMatch(rule.pattern, in); if match == 0 as [uint8] then result := NO_MATCH; else var len := StrLen(rule.replacement); var patlen := StrLen(rule.pattern); var rest := match + patlen; MemCopy(in, match-in, out); MemCopy(rule.replacement, len, out+(match-in)); CopyString(rest, out+(match-in)+len); if rule.terminates != 0 then result := HALT; else result := CONTINUE; end if; end if;
end sub;
sub ApplyRules(rules: [Rule], buffer: [uint8]): (r: [uint8]) is
var outbuf: uint8[256]; var rule := rules; r := buffer;
while rule != 0 as [Rule] loop case ApplyRule(rule, buffer, &outbuf[0]) is when NO_MATCH: rule := rule.next; when HALT: CopyString(&outbuf[0], buffer); return; when CONTINUE: CopyString(&outbuf[0], buffer); rule := rules; end case; end loop;
end sub;
sub ReadFile(filename: [uint8]): (rules: [Rule]) is
var linebuf: uint8[256]; var fcb: FCB; var bufptr := &linebuf[0];
rules := 0 as [Rule]; var prevRule := 0 as [Rule];
if FCBOpenIn(&fcb, filename) != 0 then print("Cannot open file: "); print(filename); print_nl(); ExitWithError(); end if; var length := FCBExt(&fcb); var ch: uint8 := 1; while length != 0 and ch != 0 loop ch := FCBGetChar(&fcb); length := length - 1; [bufptr] := ch; bufptr := @next bufptr;
if ch == '\n' then [bufptr] := 0; bufptr := &linebuf[0]; var rule := ParseRule(&linebuf[0]); if rule != 0 as [Rule] then if rules == 0 as [Rule] then rules := rule; end if; if prevRule != 0 as [Rule] then prevRule.next := rule; end if; prevRule := rule; end if; end if; end loop; var dummy := FCBClose(&fcb);
end sub;
ArgvInit(); var fname := ArgvNext(); if fname == 0 as [uint8] then
print("usage: markov [pattern file] [pattern]\n"); ExitWithError();
end if;
var patbuf: uint8[256]; var patptr := &patbuf[0]; loop
var patpart := ArgvNext(); if patpart == 0 as [uint8] then if patptr != &patbuf[0] then patptr := @prev patptr; end if; [patptr] := 0; break; end if; var partlen := StrLen(patpart); MemCopy(patpart, partlen, patptr); patptr := patptr + partlen + 1; [@prev patptr] := ' ';
end loop;
print(ApplyRules(ReadFile(fname), &patbuf[0])); print_nl();</lang>
- Output:
$ ./markov.386 ruleset1.mkv "I bought a B of As from T S." I bought a bag of apples from my brother. $ ./markov.386 ruleset2.mkv "I bought a B of As from T S." I bought a bag of apples from T shop. $ ./markov.386 ruleset3.mkv "I bought a B of As W my Bgage from T S." I bought a bag of apples with my money from T shop. $ ./markov.386 ruleset4.mkv "_1111*11111_" 11111111111111111111 $ ./markov.386 ruleset5.mkv "000000A000000" 00011H1111000
D
<lang d>void main() {
import std.stdio, std.file, std.regex, std.string, std.range, std.functional;
const rules = "markov_rules.txt".readText.splitLines.split(""); auto tests = "markov_tests.txt".readText.splitLines; auto re = ctRegex!(r"^([^#]*?)\s+->\s+(\.?)(.*)"); // 160 MB RAM.
alias slZip = curry!(zip, StoppingPolicy.requireSameLength); foreach (test, const rule; slZip(tests, rules)) { const origTest = test.dup;
string[][] capt; foreach (const line; rule) { auto m = line.match(re); if (!m.empty) { //capt.put(m.captures.dropOne); capt ~= m.captures.dropOne.array; } }
REDO: const copy = test; foreach (const c; capt) { test = test.replace(c[0], c[2]); if (c[1] == ".") break; if (test != copy) goto REDO; } writefln("%s\n%s\n", origTest, test); }
}</lang>
- Output:
I bought a B of As from T S. I bought a bag of apples from my brother. I bought a B of As from T S. I bought a bag of apples from T shop. I bought a B of As W my Bgage from T S. I bought a bag of apples with my money from T shop. _1111*11111_ 11111111111111111111 000000A000000 00011H1111000
Déjà Vu
This implementation expect the initial text on the command line and the ruleset on STDIN. <lang dejavu>(remove-comments) text:
] for line in text: if and line not starts-with line "#": line [
(markov-parse) text:
] for line in text: local :index find line " -> " local :pat slice line 0 index local :rep slice line + index 4 len line local :term starts-with rep "." if term: set :rep slice rep 1 len rep & pat & term rep [
markov-parse:
(markov-parse) (remove-comments) split !decode!utf-8 !read!stdin "\n"
(markov-tick) rules start:
for rule in copy rules: local :pat &< rule local :rep &> dup &> rule local :term &< local :index find start pat if < -1 index: ) slice start + index len pat len start rep slice start 0 index concat( return term true start
markov rules:
true while: not (markov-tick) rules
!. markov markov-parse get-from !args 1</lang>
EchoLisp
<lang scheme>
- rule
- = (pattern replacement [#t terminal])
(define-syntax-rule (pattern rule) (first rule)) (define-syntax-rule (repl sule) (second rule)) (define-syntax-rule (term? rule) (!empty? (cddr rule)))
- (alpha .beta )--> (alpha beta #t)
(define (term-rule rule)
(if (string=? (string-first (repl rule)) ".") (list (pattern rule) (string-rest (repl rule)) #t) rule ))
- returns list of rules
(define (parse-rules lines)
(map term-rule (for/list [(line (string-split lines "\n"))] #:continue (string=? (string-first line) "#") (map string-trim (string-split (string-replace line "/\\t/g" " ") " -> ")))))
- markov machine
(define (markov i-string rules)
(while (for/fold (run #f) ((rule rules)) #:when (string-index (pattern rule) i-string) (set! i-string (string-replace i-string (pattern rule) (repl rule))) ;;(writeln rule i-string) ;; uncomment for trace #:break (term? rule) => #f #:break #t => #t )) i-string)
(define (task i-string RS)
(markov i-string (parse-rules RS)))
</lang>
- Output:
(define RS1 #<< # This rules file is extracted from Wikipedia: # http://en.wikipedia.org/wiki/Markov_Algorithm A -> apple B -> bag C -> chinchard S -> shop T -> the the shop -> my brother a never used -> .terminating rule >>#) ;; [ Other rules sets here ...] (define i-string-1 "I bought a B of As and Cs from T S.") (define i-string-2 "I bought a B of As from T S.") (define i-string-3 "I bought a B of As W my Bgage from T S.") (define i-string-4 "_1111*11111_") (define i-string-5 "000000A000000") (task i-string-1 RS1) → "I bought a bag of apples and chinchards from my brother." (task i-string-2 RS2) → "I bought a bag of apples from T shop." (task i-string-3 RS3) → "I bought a bag of apples with my money from T shop." (task i-string-4 RS4) → "11111111111111111111" (task i-string-5 RS5) → "00011H1111000"
F#
Using Partial Active Pattern to simplify pattern matching.
<lang fsharp>open System open System.IO open System.Text.RegularExpressions
type Rule = {
matches : Regex replacement : string terminate : bool
}
let (|RegexMatch|_|) regexStr input =
let m = Regex.Match(input, regexStr, RegexOptions.ExplicitCapture) if m.Success then Some (m) else None
let (|RuleReplace|_|) rule input =
let replaced = rule.matches.Replace(input, rule.replacement, 1, 0) if input = replaced then None else Some (replaced, rule.terminate)
let parseRules line =
match line with | RegexMatch "^#" _ -> None | RegexMatch "(?<pattern>.*?)\s+->\s+(?<replacement>.*)$" m -> let replacement = (m.Groups.Item "replacement").Value let terminate = replacement.Length > 0 && replacement.Substring(0,1) = "." let pattern = (m.Groups.Item "pattern").Value Some { matches = pattern |> Regex.Escape |> Regex; replacement = if terminate then replacement.Substring(1) else replacement; terminate = terminate } | _ -> failwith "illegal rule definition"
let rec applyRules input = function | [] -> (input, true) | rule::rules ->
match input with | RuleReplace rule (withReplacement, terminate) -> (withReplacement, terminate) | _ -> applyRules input rules
[<EntryPoint>] let main argv =
let rules = File.ReadAllLines argv.[0] |> Array.toList |> List.choose parseRules let rec run input = let output, terminate = applyRules input rules if terminate then output else run output
Console.ReadLine() |> run |> printfn "%s" 0</lang>
- Output:
H:\RosettaCode\ExecMarkovAlgo>echo I bought a B of As from T S. | Fsharp\RosettaCode\bin\Debug\RosettaCode.exe m1 I bought a bag of apples from my brother. H:\RosettaCode\ExecMarkovAlgo>echo I bought a B of As from T S.| Fsharp\RosettaCode\bin\Debug\RosettaCode.exe m2 I bought a bag of apples from T shop. H:\RosettaCode\ExecMarkovAlgo>echo I bought a B of As W my Bgage from T S.| Fsharp\RosettaCode\bin\Debug\RosettaCode.exe m3 I bought a bag of apples with my money from T shop. H:\RosettaCode\ExecMarkovAlgo>echo _1111*11111_ | Fsharp\RosettaCode\bin\Debug\RosettaCode.exe m4 11111111111111111111 H:\RosettaCode\ExecMarkovAlgo>echo 000000A000000 | Fsharp\RosettaCode\bin\Debug\RosettaCode.exe m5 00011H1111000
Go
<lang go>package main
import (
"fmt" "regexp" "strings"
)
type testCase struct {
ruleSet, sample, output string
}
func main() {
fmt.Println("validating", len(testSet), "test cases") var failures bool for i, tc := range testSet { if r, ok := interpret(tc.ruleSet, tc.sample); !ok { fmt.Println("test", i+1, "invalid ruleset") failures = true } else if r != tc.output { fmt.Printf("test %d: got %q, want %q\n", i+1, r, tc.output) failures = true } } if !failures { fmt.Println("no failures") }
}
func interpret(ruleset, input string) (string, bool) {
if rules, ok := parse(ruleset); ok { return run(rules, input), true } return "", false
}
type rule struct {
pat string rep string term bool
}
var (
rxSet = regexp.MustCompile(ruleSet) rxEle = regexp.MustCompile(ruleEle) ruleSet = `(?m:^(?:` + ruleEle + `)*$)` ruleEle = `(?:` + comment + `|` + ruleRe + `)\n+` comment = `#.*` ruleRe = `(.*)` + ws + `->` + ws + `([.])?(.*)` ws = `[\t ]+`
)
func parse(rs string) ([]rule, bool) {
if !rxSet.MatchString(rs) { return nil, false } x := rxEle.FindAllStringSubmatchIndex(rs, -1) var rules []rule for _, x := range x { if x[2] > 0 { rules = append(rules, rule{pat: rs[x[2]:x[3]], term: x[4] > 0, rep: rs[x[6]:x[7]]}) } } return rules, true
}
func run(rules []rule, s string) string { step1:
for _, r := range rules { if f := strings.Index(s, r.pat); f >= 0 { s = s[:f] + r.rep + s[f+len(r.pat):] if r.term { return s } goto step1 } } return s
}
// text all cut and paste from RC task page var testSet = []testCase{
{`# This rules file is extracted from Wikipedia:
A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule `,
`I bought a B of As from T S.`, `I bought a bag of apples from my brother.`, }, {`# Slightly modified from the rules on Wikipedia
A -> apple B -> bag S -> .shop T -> the the shop -> my brother a never used -> .terminating rule `,
`I bought a B of As from T S.`, `I bought a bag of apples from T shop.`, }, {`# BNF Syntax testing rules
A -> apple WWWW -> with Bgage -> ->.* B -> bag ->.* -> money W -> WW S -> .shop T -> the the shop -> my brother a never used -> .terminating rule `,
`I bought a B of As W my Bgage from T S.`, `I bought a bag of apples with my money from T shop.`, }, {`### Unary Multiplication Engine, for testing Markov Algorithm implementations
- By Donal Fellows.
- Unary addition engine
_+1 -> _1+ 1+1 -> 11+
- Pass for converting from the splitting of multiplication into ordinary
- addition
1! -> !1 ,! -> !+ _! -> _
- Unary multiplication by duplicating left side, right side times
1*1 -> x,@y 1x -> xX X, -> 1,1 X1 -> 1X _x -> _X ,x -> ,X y1 -> 1y y_ -> _
- Next phase of applying
1@1 -> x,@y 1@_ -> @_ ,@_ -> !_ ++ -> +
- Termination cleanup for addition
_1 -> 1 1+_ -> 1 _+_ -> `,
`_1111*11111_`, `11111111111111111111`, }, {`# Turing machine: three-state busy beaver
- state A, symbol 0 => write 1, move right, new state B
A0 -> 1B
- state A, symbol 1 => write 1, move left, new state C
0A1 -> C01 1A1 -> C11
- state B, symbol 0 => write 1, move left, new state A
0B0 -> A01 1B0 -> A11
- state B, symbol 1 => write 1, move right, new state B
B1 -> 1B
- state C, symbol 0 => write 1, move left, new state B
0C0 -> B01 1C0 -> B11
- state C, symbol 1 => write 1, move left, halt
0C1 -> H01 1C1 -> H11 `,
`000000A000000`, `00011H1111000`, },
}</lang>
- Output:
validating 5 test cases no failures
Groovy
<lang groovy>def markovInterpreterFor = { rules ->
def ruleMap = [:] rules.eachLine { line -> (line =~ /\s*(.+)\s->\s([.]?)(.+)\s*/).each { text, key, terminating, value -> if (key.startsWith('#')) { return } ruleMap[key] = [text: value, terminating: terminating] } } [interpret: { text -> def originalText = while (originalText != text) { originalText = text for (Map.Entry e : ruleMap.entrySet()) { if (text.indexOf(e.key) >= 0) { text = text.replace(e.key, e.value.text) if (e.value.terminating) { return text } break } } } text }]
}</lang> The test code is below (with the markov rulesets 2..5 elided): <lang groovy>def verify = { ruleset ->
[withInput: { text -> [hasOutput: { expected -> def result = ruleset.interpret(text) println "Input: '$text' has output: '$result'" assert expected == result }] }]
}
def ruleset1 = markovInterpreterFor("""
- This rules file is extracted from Wikipedia:
- http://en.wikipedia.org/wiki/Markov_Algorithm
A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule""") println ruleset1.interpret('I bought a B of As from T S.') verify ruleset1 withInput 'I bought a bag of apples from T shop.' hasOutput 'I bought a bag of apples from my brother.'
def ruleset2 = markovInterpreterFor("""...""") verify ruleset2 withInput 'I bought a B of As from T S.' hasOutput 'I bought a bag of apples from T shop.'
def ruleset3 = markovInterpreterFor("""...""") verify ruleset3 withInput 'I bought a B of As W my Bgage from T S.' hasOutput 'I bought a bag of apples with my money from T shop.'
def ruleset4 = markovInterpreterFor("""...""") verify ruleset4 withInput '_1111*11111_' hasOutput '11111111111111111111'
def ruleset5 = markovInterpreterFor("""...""") verify ruleset5 withInput '000000A000000' hasOutput '00011H1111000'</lang>
- Output:
I bought a bag of apples from my brother. Input: 'I bought a bag of apples from T shop.' has output: 'I bought a bag of apples from my brother.' Input: 'I bought a B of As from T S.' has output: 'I bought a bag of apples from T shop.' Input: 'I bought a B of As W my Bgage from T S.' has output: 'I bought a bag of apples with my money from T shop.' Input: '_1111*11111_' has output: '11111111111111111111' Input: '000000A000000' has output: '00011H1111000'
Haskell
This program expects a source file as an argument and uses the standard input and output devices for the algorithm's I/O.
<lang haskell>import Data.List (isPrefixOf) import Data.Maybe (catMaybes) import Control.Monad import Text.ParserCombinators.Parsec import System.IO import System.Environment (getArgs)
main = do
args <- getArgs unless (length args == 1) $ fail "Please provide exactly one source file as an argument." let sourcePath = head args source <- readFile sourcePath input <- getContents case parse markovParser sourcePath source of Right rules -> putStr $ runMarkov rules input Left err -> hPutStrLn stderr $ "Parse error at " ++ show err
data Rule = Rule
{from :: String, terminating :: Bool, to :: String}
markovParser :: Parser [Rule] markovParser = liftM catMaybes $
(comment <|> rule) `sepEndBy` many1 newline where comment = char '#' >> skipMany nonnl >> return Nothing rule = liftM Just $ liftM3 Rule (manyTill (nonnl <?> "pattern character") $ try arrow) (succeeds $ char '.') (many nonnl) arrow = ws >> string "->" >> ws <?> "whitespace-delimited arrow" nonnl = noneOf "\n" ws = many1 $ oneOf " \t" succeeds p = option False $ p >> return True
runMarkov :: [Rule] -> String -> String runMarkov rules s = f rules s
where f [] s = s f (Rule from terminating to : rs) s = g "" s where g _ "" = f rs s g before ahead@(a : as) = if from `isPrefixOf` ahead then let new = reverse before ++ to ++ drop (length from) ahead in if terminating then new else f rules new else g (a : before) as</lang>
Icon and Unicon
<lang unicon>procedure main(A)
rules := loadRules(open(A[1],"r")) every write(line := !&input, " -> ",apply(rules, line))
end
record rule(pat, term, rep)
procedure loadRules(f)
rules := [] every !f ? if not ="#" then put(rules, rule(1(trim(tab(find("->"))),move(2),tab(many(' \t'))), (="."|&null), trim(tab(0)))) return rules
end
procedure apply(rules, line)
s := line repeat { s ?:= tab(find((r := !rules).pat)) || r.rep || (move(*r.pat),tab(0)) if (s == line) | \r.term then return s else line := s }
end</lang>
Sample runs using above rule sets and test strings:
->ma mars.1 I bought a B of As from T S. I bought a B of As from T S. -> I bought a bag of apples from my brother. ->ma mars.2 I bought a B of As from T S. I bought a B of As from T S. -> I bought a bag of apples from T shop. ->ma mars.3 I bought a B of As W my Bgage from T S. I bought a B of As W my Bgage from T S. -> I bought a bag of apples with my money from T shop. ->ma mars.4 _1111*11111_ _1111*11111_ -> 11111111111111111111 ->ma mars.5 000000A000000 000000A000000 -> 00011H1111000
J
Solution:<lang j>require'strings regex'
markovLexer =: verb define
rules =. LF cut TAB&=`(,:&' ')}y rules =. a: -.~ (dltb@:{.~ i:&'#')&.> rules rules =. 0 _1 {"1 '\s+->\s+' (rxmatch rxcut ])S:0 rules (,. ] (}.&.>~ ,. ]) ('.'={.)&.>)/ |: rules
)
replace =: dyad define
'index patternLength replacement'=. x 'head tail' =. index split y head, replacement, patternLength }. tail
)
matches =: E. i. 1:
markov =: dyad define
ruleIdx =. 0 [ rules =. markovLexer x while. ruleIdx < #rules do. 'pattern replacement terminating' =. ruleIdx { rules ruleIdx =. 1 + ruleIdx if. (#y) > index =. pattern matches y do. y =. (index ; (#pattern) ; replacement) replace y ruleIdx =. _ * terminating end. end. y
)</lang>
Example:<lang j> m1 =. noun define
# This rules file is extracted from Wikipedia: # http://en.wikipedia.org/wiki/Markov_Algorithm A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule
)
m1 markov 'I bought a B of As from T S.'
I bought a bag of apples from my brother. </lang> Discussion: The J implementation correctly processes all the rulesets. More details are available on the the talk page.
Java
<lang java>import java.io.IOException; import java.nio.charset.StandardCharsets; import java.nio.file.Files; import java.nio.file.Paths; import java.util.ArrayList; import java.util.List; import java.util.regex.Matcher; import java.util.regex.Pattern;
public class Markov {
public static void main(String[] args) throws IOException {
List<String[]> rules = readRules("markov_rules.txt"); List<String> tests = readTests("markov_tests.txt");
Pattern pattern = Pattern.compile("^([^#]*?)\\s+->\\s+(\\.?)(.*)");
for (int i = 0; i < tests.size(); i++) { String origTest = tests.get(i);
List<String[]> captures = new ArrayList<>(); for (String rule : rules.get(i)) { Matcher m = pattern.matcher(rule); if (m.find()) { String[] groups = new String[m.groupCount()]; for (int j = 0; j < groups.length; j++) groups[j] = m.group(j + 1); captures.add(groups); } }
String test = origTest; String copy = test; for (int j = 0; j < captures.size(); j++) { String[] c = captures.get(j); test = test.replace(c[0], c[2]); if (c[1].equals(".")) break; if (!test.equals(copy)) { j = -1; // redo loop copy = test; } } System.out.printf("%s\n%s\n\n", origTest, test); } }
private static List<String> readTests(String path) throws IOException { return Files.readAllLines(Paths.get(path), StandardCharsets.UTF_8); }
private static List<String[]> readRules(String path) throws IOException { String ls = System.lineSeparator(); String lines = new String(Files.readAllBytes(Paths.get(path)), "UTF-8"); List<String[]> rules = new ArrayList<>(); for (String line : lines.split(ls + ls)) rules.add(line.split(ls)); return rules; }
}</lang>
Output:
I bought a B of As from T S. I bought a bag of apples from my brother. I bought a B of As from T S. I bought a bag of apples from T shop. I bought a B of As W my Bgage from T S. I bought a bag of apples with my money from T shop. _1111*11111_ 11111111111111111111 000000A000000 00011H1111000
JavaScript
<lang javascript>/**
* Take a ruleset and return a function which takes a string to which the rules * should be applied. * @param {string} ruleSet * @returns {function(string): string} */
const markov = ruleSet => {
/** * Split a string at an index * @param {string} s The string to split * @param {number} i The index number where to split. * @returns {Array<string>} */ const splitAt = (s, i) => [s.slice(0, i), s.slice(i)];
/** * Strip a leading number of chars from a string. * @param {string} s The string to strip the chars from * @param {string} strip A string who's length will determine the number of * chars to strip. * @returns {string} */ const stripLeading = (s, strip) => s.split() .filter((e, i) => i >= strip.length).join();
/** * Replace the substring in the string. * @param {string} s The string to replace the substring in * @param {string} find The sub-string to find * @param {string} rep The replacement string * @returns {string} */ const replace = (s, find, rep) => { let result = s; if (s.indexOf(find) >= 0) { const a = splitAt(s, s.indexOf(find)); result = [a[0], rep, stripLeading(a[1], find)].join(); } return result; };
/** * Convert a ruleset string into a map * @param {string} ruleset * @returns {Map} */ const makeRuleMap = ruleset => ruleset.split('\n') .filter(e => !e.startsWith('#')) .map(e => e.split(' -> ')) .reduce((p,c) => p.set(c[0], c[1]), new Map());
/** * Recursively apply the ruleset to the string. * @param {Map} rules The rules to apply * @param {string} s The string to apply the rules to * @returns {string} */ const parse = (rules, s) => { const o = s; for (const [k, v] of rules.entries()) { if (v.startsWith('.')) { s = replace(s, k, stripLeading(v, '.')); break; } else { s = replace(s, k, v); if (s !== o) { break; } } } return o === s ? s : parse(rules, s); };
const ruleMap = makeRuleMap(ruleSet);
return str => parse(ruleMap, str)
};
const ruleset1 = `# This rules file is extracted from Wikipedia:
A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule`;
const ruleset2 = `# Slightly modified from the rules on Wikipedia A -> apple B -> bag S -> .shop T -> the the shop -> my brother a never used -> .terminating rule`;
const ruleset3 = `# BNF Syntax testing rules A -> apple WWWW -> with Bgage -> ->.* B -> bag ->.* -> money W -> WW S -> .shop T -> the the shop -> my brother a never used -> .terminating rule`;
const ruleset4 = `### Unary Multiplication Engine, for testing Markov Algorithm implementations
- By Donal Fellows.
- Unary addition engine
_+1 -> _1+ 1+1 -> 11+
- Pass for converting from the splitting of multiplication into ordinary
- addition
1! -> !1 ,! -> !+ _! -> _
- Unary multiplication by duplicating left side, right side times
1*1 -> x,@y 1x -> xX X, -> 1,1 X1 -> 1X _x -> _X ,x -> ,X y1 -> 1y y_ -> _
- Next phase of applying
1@1 -> x,@y 1@_ -> @_ ,@_ -> !_ ++ -> +
- Termination cleanup for addition
_1 -> 1 1+_ -> 1 _+_ -> `;
const ruleset5 = `# Turing machine: three-state busy beaver
- state A, symbol 0 => write 1, move right, new state B
A0 -> 1B
- state A, symbol 1 => write 1, move left, new state C
0A1 -> C01 1A1 -> C11
- state B, symbol 0 => write 1, move left, new state A
0B0 -> A01 1B0 -> A11
- state B, symbol 1 => write 1, move right, new state B
B1 -> 1B
- state C, symbol 0 => write 1, move left, new state B
0C0 -> B01 1C0 -> B11
- state C, symbol 1 => write 1, move left, halt
0C1 -> H01 1C1 -> H11`;
console.log(markov(ruleset1)('I bought a B of As from T S.')); console.log(markov(ruleset2)('I bought a B of As from T S.')); console.log(markov(ruleset3)('I bought a B of As W my Bgage from T S.')); console.log(markov(ruleset4)('_1111*11111_')); console.log(markov(ruleset5)('000000A000000'));</lang> Output:
I bought a bag of apples from my brother. I bought a bag of apples from T shop. I bought a bag of apples with my money from T shop. 11111111111111111111 00011H1111000
Julia
Module: <lang julia>module MarkovAlgos
struct MarkovRule{F,T}
patt::F repl::T term::Bool
end
isterminating(r::MarkovRule) = r.term Base.show(io::IO, rule::MarkovRule) =
print(io, rule.patt, " → ", isterminating(rule) ? "." : "", rule.repl)
function Base.convert(::Type{MarkovRule}, s::AbstractString)
rmatch = match(r"^(.+)\s+->\s*(\.)?(.*)?$", s) if rmatch ≡ nothing || isempty(rmatch.captures) throw(ParseError("not valid rule: " * s)) end patt, term, repl = rmatch.captures return MarkovRule(patt, repl ≢ nothing ? repl : "", term ≢ nothing)
end
function ruleset(file::Union{AbstractString,IO})
ruleset = Vector{MarkovRule}(0) for line in eachline(file) ismatch(r"(^#|^\s*$)", line) || push!(ruleset, MarkovRule(line)) end return ruleset
end
apply(text::AbstractString, rule::MarkovRule) = replace(text, rule.patt, rule.repl) function apply(file::Union{AbstractString,IO}, ruleset::AbstractVector{<:MarkovRule})
text = readstring(file) redo = !isempty(text) while redo matchrule = false for rule in ruleset if contains(text, rule.patt) matchrule = true text = apply(text, rule) redo = !isterminating(rule) break end end redo = redo && matchrule end return text
end
end # module MarkovAlgos</lang>
Main: <lang julia>include("module.jl")
let rulesets = @.("data/markovrules0" * string(1:5) * ".txt"),
ruletest = @.("data/markovtest0" * string(1:5) * ".txt") for i in eachindex(rulesets, ruletest) rules = MarkovAlgos.ruleset(rulesets[i]) println("# Example n.$i") println("Original:\n", readstring(ruletest[i])) println("Transformed:\n", MarkovAlgos.apply(ruletest[i], rules)) end
end</lang>
- Output:
# Example n.1 Original: I bought a B of As from T S. Transformed: I bought a bag of apples from my brother. # Example n.2 Original: I bought a B of As from T S. Transformed: I bought a bag of apples from T shop. # Example n.3 Original: I bought a B of As W my Bgage from T S. Transformed: I bought a bag of apples with my baggage from T shop. # Example n.4 Original: _1111*11111_ Transformed: 11111111111111111111 # Example n.5 Original: 000000A000000 Transformed: 00011H1111000
Kotlin
<lang scala>// version 1.1.51
import java.io.File import java.util.regex.Pattern
/* rulesets assumed to be separated by a blank line in file */ fun readRules(path: String): List<List<String>> {
val ls = System.lineSeparator() return File(path).readText().split("$ls$ls").map { it.split(ls) }
}
/* tests assumed to be on consecutive lines */ fun readTests(path: String) = File(path).readLines()
fun main(args: Array<String>) {
val rules = readRules("markov_rules.txt") val tests = readTests("markov_tests.txt") val pattern = Pattern.compile("^([^#]*?)\\s+->\\s+(\\.?)(.*)")
for ((i, origTest) in tests.withIndex()) { val captures = mutableListOf<List<String>>() for (rule in rules[i]) { val m = pattern.matcher(rule) if (m.find()) { val groups = List<String>(m.groupCount()) { m.group(it + 1) } captures.add(groups) } } var test = origTest
do { val copy = test var redo = false for (c in captures) { test = test.replace(c[0], c[2]) if (c[1] == ".") break if (test != copy) { redo = true; break } } } while (redo)
println("$origTest\n$test\n") }
}</lang>
- Output:
I bought a B of As from T S. I bought a bag of apples from my brother. I bought a B of As from T S. I bought a bag of apples from T shop. I bought a B of As W my Bgage from T S. I bought a bag of apples with my money from T shop. _1111*11111_ 11111111111111111111 000000A000000 00011H1111000
Lua
<lang lua>-- utility method to escape punctuation function normalize(str)
local result = str:gsub("(%p)", "%%%1") -- print(result) return result
end
-- utility method to split string into lines function get_lines(str)
local t = {} for line in str:gmatch("([^\n\r]*)[\n\r]*") do table.insert(t, line) end return t
end
local markov = {} local MARKOV_RULE_PATTERN = "(.+)%s%-%>%s(%.?)(.*)"
function markov.rule(pattern,replacement,terminating)
return { pattern = pattern, replacement = replacement, terminating = (terminating == ".") }, normalize(pattern)
end
function markov.make_rules(sample)
local lines = get_lines(sample) local rules = {} local finders = {} for i,line in ipairs(lines) do if not line:find("^#") then s,e,pat,term,rep = line:find(MARKOV_RULE_PATTERN) if s then r, p = markov.rule(pat,rep,term) rules[p] = r table.insert(finders, p) end end end return { rules = rules, finders = finders }
end
function markov.execute(state, sample_input)
local rules, finders = state.rules, state.finders local found = false -- did we find any rule? local terminate = false
repeat found = false
for i,v in ipairs(finders) do
local found_now = false -- did we find this rule? if sample_input:find(v) then found = true found_now = true end sample_input = sample_input:gsub(v, rules[v].replacement, 1) -- handle terminating rules if found_now then if rules[v].terminating then terminate = true end break end
end
until not found or terminate
return sample_input end
local grammar1 = [[
- This rules file is extracted from Wikipedia:
- http://en.wikipedia.org/wiki/Markov_Algorithm
A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule ]]
local grammar2 = [[
- Slightly modified from the rules on Wikipedia
A -> apple B -> bag S -> .shop T -> the the shop -> my brother a never used -> .terminating rule ]]
local grammar3 = [[
- BNF Syntax testing rules
A -> apple WWWW -> with Bgage -> ->.* B -> bag ->.* -> money W -> WW S -> .shop T -> the the shop -> my brother a never used -> .terminating rule ]]
local grammar4 = [[
- Unary Multiplication Engine, for testing Markov Algorithm implementations
- By Donal Fellows.
- Unary addition engine
_+1 -> _1+ 1+1 -> 11+
- Pass for converting from the splitting of multiplication into ordinary
- addition
1! -> !1 ,! -> !+ _! -> _
- Unary multiplication by duplicating left side, right side times
1*1 -> x,@y 1x -> xX X, -> 1,1 X1 -> 1X _x -> _X ,x -> ,X y1 -> 1y y_ -> _
- Next phase of applying
1@1 -> x,@y 1@_ -> @_ ,@_ -> !_ ++ -> +
- Termination cleanup for addition
_1 -> 1 1+_ -> 1 _+_ -> ]]
local grammar5 = [[
- Turing machine: three-state busy beaver
- state A, symbol 0 => write 1, move right, new state B
A0 -> 1B
- state A, symbol 1 => write 1, move left, new state C
0A1 -> C01 1A1 -> C11
- state B, symbol 0 => write 1, move left, new state A
0B0 -> A01 1B0 -> A11
- state B, symbol 1 => write 1, move right, new state B
B1 -> 1B
- state C, symbol 0 => write 1, move left, new state B
0C0 -> B01 1C0 -> B11
- state C, symbol 1 => write 1, move left, halt
0C1 -> H01 1C1 -> H11 ]]
local text1 = "I bought a B of As from T S." local text2 = "I bought a B of As W my Bgage from T S." local text3 = '_1111*11111_' local text4 = '000000A000000'
function do_markov(rules, input, output)
local m = markov.make_rules(rules) input = markov.execute(m, input) assert(input == output) print(input)
end
do_markov(grammar1, text1, 'I bought a bag of apples from my brother.') do_markov(grammar2, text1, 'I bought a bag of apples from T shop.') -- stretch goals do_markov(grammar3, text2, 'I bought a bag of apples with my money from T shop.') do_markov(grammar4, text3, '11111111111111111111') do_markov(grammar5, text4, '00011H1111000')</lang>
Mathematica / Wolfram Language
<lang mathematica>markov[ruleset_, text_] :=
Module[{terminating = False, output = text, rules = StringCases[ ruleset, {StartOfLine ~~ pattern : Except["\n"] .. ~~ " " | "\t" .. ~~ "->" ~~ " " | "\t" .. ~~ dot : "" | "." ~~ replacement : Except["\n"] .. ~~ EndOfLine :> {pattern, replacement, dot == "."}}]}, While[! terminating, terminating = True; Do[If[! StringFreeQ[output, rule1], output = StringReplace[output, rule1 -> rule2]; If[! rule3, terminating = False]; Break[]], {rule, rules}]]; output];</lang>
Example: <lang mathematica>markov["# Turing machine: three-state busy beaver
# # state A, symbol 0 => write 1, move right, new state B A0 -> 1B # state A, symbol 1 => write 1, move left, new state C 0A1 -> C01 1A1 -> C11 # state B, symbol 0 => write 1, move left, new state A 0B0 -> A01 1B0 -> A11 # state B, symbol 1 => write 1, move right, new state B B1 -> 1B # state C, symbol 0 => write 1, move left, new state B 0C0 -> B01 1C0 -> B11 # state C, symbol 1 => write 1, move left, halt 0C1 -> H01 1C1 -> H11", "000000A000000"]</lang>
Output:
"00011H1111000"
МК-61/52
<lang> 9 П4
КИП4 [x] П7 Вx {x} П8 ИП8 ИПE * П8 {x} x=0 08 П5 ИП9 П1 lg [x] 10^x П3 ИП1 П2 Сx П6 ИП2 ИП7 - x=0 70 ИП9 ^ lg [x] 1 + ИП5 - 10^x / [x] ИП6 ИП8 x#0 50 lg [x] 1 + + 10^x * ИП9 ИП6 10^x П7 / {x} ИП7 * + ИП8 ИП7 * + П9 С/П БП 00 x>=0 80 КИП6 ИП2 ИПE / [x] П2 x=0 26 КИП5 ИП1 ИП3 / {x} ИП3 * П1 ИП3 ИПE / [x] П3 x=0 22 ИП4 ИП0 - 9 - x=0 02 С/П</lang>
Under the rules of left 4 registers, under the word has 8 character cells, the alphabet of the digits from 1 to 8. Rules are placed in "123,456", where "123" is a fragment, and "456" is to be replaced, in the registers of the РA to РD. The number of rules is stored in Р0, the initial word is in Р9. Number triggered rule is the last digit registration Р4 (0 to 3), if no rule did not work, the indicator 0, otherwise the current word to be processed. In РE is stored 10.
Nim
<lang Nim>import strutils, strscans
type Rule = object
pattern: string # Input pattern. replacement: string # Replacement string (may be empty). terminating: bool # "true" if terminating rule.
- ---------------------------------------------------------------------------------------------------
func parse(rules: string): seq[Rule] =
## Parse a rule set to build a sequence of rules.
var linecount = 0 for line in rules.splitLines():
inc linecount if line.startsWith('#'): continue if line.strip.len == 0: continue
# Scan the line. var pat, rep: string var terminating = false if not line.scanf("$+ -> $*", pat, rep): raise newException(ValueError, "Invalid rule at line " & $linecount)
if rep.startsWith('.'): # Terminating rule. rep = rep[1..^1] terminating = true
result.add(Rule(pattern: pat, replacement: rep, terminating: terminating))
- ---------------------------------------------------------------------------------------------------
func apply(text: string; rules: seq[Rule]): string =
## Apply a set of rules to a text and return the result.
result = text var changed = true
while changed: changed = false # Try to apply the rules in sequence. for rule in rules: if result.find(rule.pattern) >= 0: # Found a rule to apply. result = result.replace(rule.pattern, rule.replacement) if rule.terminating: return changed = true break
- ———————————————————————————————————————————————————————————————————————————————————————————————————
const SampleTexts = ["I bought a B of As from T S.",
"I bought a B of As from T S.", "I bought a B of As W my Bgage from T S.", "_1111*11111_", "000000A000000"]
const Rulesets = [
- ................................................
"""# This rules file is extracted from Wikipedia:
A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule""",
- ................................................
"""# Slightly modified from the rules on Wikipedia A -> apple B -> bag S -> .shop T -> the the shop -> my brother a never used -> .terminating rule""",
- ................................................
"""# BNF Syntax testing rules A -> apple WWWW -> with Bgage -> ->.* B -> bag ->.* -> money W -> WW S -> .shop T -> the the shop -> my brother a never used -> .terminating rule""",
- ................................................
"""### Unary Multiplication Engine, for testing Markov Algorithm implementations
- By Donal Fellows.
- Unary addition engine
_+1 -> _1+ 1+1 -> 11+
- Pass for converting from the splitting of multiplication into ordinary
- addition
1! -> !1 ,! -> !+ _! -> _
- Unary multiplication by duplicating left side, right side times
1*1 -> x,@y 1x -> xX X, -> 1,1 X1 -> 1X _x -> _X ,x -> ,X y1 -> 1y y_ -> _
- Next phase of applying
1@1 -> x,@y 1@_ -> @_ ,@_ -> !_ ++ -> +
- Termination cleanup for addition
_1 -> 1 1+_ -> 1 _+_ -> """,
- ................................................
"""# Turing machine: three-state busy beaver
- state A, symbol 0 => write 1, move right, new state B
A0 -> 1B
- state A, symbol 1 => write 1, move left, new state C
0A1 -> C01 1A1 -> C11
- state B, symbol 0 => write 1, move left, new state A
0B0 -> A01 1B0 -> A11
- state B, symbol 1 => write 1, move right, new state B
B1 -> 1B
- state C, symbol 0 => write 1, move left, new state B
0C0 -> B01 1C0 -> B11
- state C, symbol 1 => write 1, move left, halt
0C1 -> H01 1C1 -> H11"""
]
for n, ruleset in RuleSets:
let rules = ruleset.parse() echo SampleTexts[n].apply(rules)</lang>
- Output:
I bought a bag of apples from my brother. I bought a bag of apples from T shop. I bought a bag of apples with my money from T shop. 11111111111111111111 00011H1111000
OCaml
I'm not familiar with string processing, or parsing, so there are probably better ways to express this in OCaml. One might be with the mikmatch library which allows pattern-matching with regexps. Here I've only used the OCaml stdlib...
<lang OCaml>(* Useful for resource cleanup (such as filehandles) *) let try_finally x f g =
try let res = f x in g x; res with e -> g x; raise e
(* Substitute string 'b' for first occurance of regexp 'a' in 's';
* Raise Not_found if there was no occurance of 'a'. *)
let subst a b s =
ignore (Str.search_forward a s 0); (* to generate Not_found *) Str.replace_first a b s
let parse_rules cin =
let open Str in let rule = regexp "\\(.+\\)[ \t]+->[ \t]+\\(.*\\)" in let leader s c = String.length s > 0 && s.[0] = c in let parse_b s = if leader s '.' then (string_after s 1,true) else (s,false) in let rec parse_line rules = try let s = input_line cin in if leader s '#' then parse_line rules else if string_match rule s 0 then let a = regexp_string (matched_group 1 s) in let b,terminate = parse_b (matched_group 2 s) in parse_line ((a,b,terminate)::rules) else failwith ("parse error: "^s) with End_of_file -> rules in List.rev (parse_line [])
let rec run rules text =
let rec apply s = function | [] -> s | (a,b,term)::next -> try let s' = subst a b s in if term then s' else run rules s' with Not_found -> apply s next in apply text rules
let _ =
if Array.length Sys.argv <> 2 then print_endline "Expecting one argument: a filename where rules can be found." else let rules = try_finally (open_in Sys.argv.(1)) parse_rules close_in in (* Translate lines read from stdin, until EOF *) let rec translate () = print_endline (run rules (input_line stdin)); translate () in try translate () with End_of_file -> ()</lang>
With the above compiled to an executable 'markov', and the five rule-sets in files, strings are accepted on stdin for translation:
<~/rosetta$> markov rules1 I bought a B of As from T S. I bought a bag of apples from my brother. <~/rosetta$> markov rules2 I bought a B of As from T S. I bought a bag of apples from T shop. <~/rosetta$> markov rules3 I bought a B of As W my Bgage from T S. I bought a bag of apples with my money from T shop. <~/rosetta$> markov rules4 _1111*11111_ 11111111111111111111 <~/rosetta$> markov rules5 000000A000000 00011H1111000
Perl
This program expects a source file as an argument and uses the standard input and output devices for the algorithm's I/O.
<lang perl>@ARGV == 1 or die "Please provide exactly one source file as an argument.\n"; open my $source, '<', $ARGV[0] or die "I couldn't open \"$ARGV[0]\" for reading. ($!.)\n"; my @rules; while (<$source>)
{/\A#/ and next; my @a = /(.*?)\s+->\s+(\.?)(.*)/ or die "Syntax error: $_"; push @rules, \@a;}
close $source;
my $input = do {local $/; <STDIN>;};
OUTER:
{foreach (@rules) {my ($from, $terminating, $to) = @$_; $input =~ s/\Q$from\E/$to/ and ($terminating ? last OUTER : redo OUTER);}}
print $input;</lang>
Phix
procedure markov(string rules, input, expected) sequence subs = {}, reps = {} sequence lines = split(substitute(rules,'\t',' '),'\n') for i=1 to length(lines) do string li = lines[i] if length(li) and li[1]!='#' then integer k = match(" -> ",li) if k then subs = append(subs,trim(li[1..k-1])) reps = append(reps,trim(li[k+4..$])) end if end if end for string res = input bool term = false while 1 do bool found = false for i=1 to length(subs) do string sub = subs[i] integer k = match(sub,res) if k then found = true string rep = reps[i] if length(rep) and rep[1]='.' then rep = rep[2..$] term = true end if res[k..k+length(sub)-1] = rep exit end if if term then exit end if end for if term or not found then exit end if end while ?{input,res,iff(res=expected?"ok":"**ERROR**")} end procedure constant ruleset1 = """ # This rules file is extracted from Wikipedia: # http://en.wikipedia.org/wiki/Markov_Algorithm A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule""" markov(ruleset1,"I bought a B of As from T S.","I bought a bag of apples from my brother.") constant ruleset2 = """ # Slightly modified from the rules on Wikipedia A -> apple B -> bag S -> .shop T -> the the shop -> my brother a never used -> .terminating rule""" markov(ruleset2,"I bought a B of As from T S.","I bought a bag of apples from T shop.") constant ruleset3 = """ # BNF Syntax testing rules A -> apple WWWW -> with Bgage -> ->.* B -> bag ->.* -> money W -> WW S -> .shop T -> the the shop -> my brother a never used -> .terminating rule""" markov(ruleset3,"I bought a B of As W my Bgage from T S.","I bought a bag of apples with my money from T shop.") constant ruleset4 = """ ### Unary Multiplication Engine, for testing Markov Algorithm implementations ### By Donal Fellows. # Unary addition engine _+1 -> _1+ 1+1 -> 11+ # Pass for converting from the splitting of multiplication into ordinary # addition 1! -> !1 ,! -> !+ _! -> _ # Unary multiplication by duplicating left side, right side times 1*1 -> x,@y 1x -> xX X, -> 1,1 X1 -> 1X _x -> _X ,x -> ,X y1 -> 1y y_ -> _ # Next phase of applying 1@1 -> x,@y 1@_ -> @_ ,@_ -> !_ ++ -> + # Termination cleanup for addition _1 -> 1 1+_ -> 1 _+_ -> """ markov(ruleset4,"_1111*11111_","11111111111111111111") constant ruleset5 = """ # Turing machine: three-state busy beaver # # state A, symbol 0 => write 1, move right, new state B A0 -> 1B # state A, symbol 1 => write 1, move left, new state C 0A1 -> C01 1A1 -> C11 # state B, symbol 0 => write 1, move left, new state A 0B0 -> A01 1B0 -> A11 # state B, symbol 1 => write 1, move right, new state B B1 -> 1B # state C, symbol 0 => write 1, move left, new state B 0C0 -> B01 1C0 -> B11 # state C, symbol 1 => write 1, move left, halt 0C1 -> H01 1C1 -> H11 """ markov(ruleset5,"000000A000000","00011H1111000")
- Output:
{"I bought a B of As from T S.","I bought a bag of apples from my brother.","ok"} {"I bought a B of As from T S.","I bought a bag of apples from T shop.","ok"} {"I bought a B of As W my Bgage from T S.","I bought a bag of apples with my money from T shop.","ok"} {"_1111*11111_","11111111111111111111","ok"} {"000000A000000","00011H1111000","ok"}
PHP
<lang PHP><?php
function markov($text, $ruleset) {
$lines = explode(PHP_EOL, $ruleset); $rules = array(); foreach ($lines AS $line) { $spc = "[\t ]+"; if (empty($line) OR preg_match('/^#/', $line)) { continue; } elseif (preg_match('/^(.+)' . $spc . '->' . $spc . '(\.?)(.*)$/', $line, $matches)) { list($dummy, $pattern, $terminating, $replacement) = $matches; $rules[] = array( 'pattern' => trim($pattern), 'terminating' => ($terminating === '.'), 'replacement' => trim($replacement), ); } } do { $found = false; foreach ($rules AS $rule) { if (strpos($text, $rule['pattern']) !== FALSE) { $text = str_replace($rule['pattern'], $rule['replacement'], $text); if ($rule['terminating']) { return $text; } $found = true; break; } } } while($found); return $text;
}
$conf = array(
1 => array( 'text' => 'I bought a B of As from T S.', 'rule' => ' # This rules file is extracted from Wikipedia: # http://en.wikipedia.org/wiki/Markov_Algorithm A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule ', ), 2 => array( 'text' => 'I bought a B of As from T S.', 'rule' => ' # Slightly modified from the rules on Wikipedia A -> apple B -> bag S -> .shop T -> the the shop -> my brother a never used -> .terminating rule ', ), 3 => array( 'text' => 'I bought a B of As W my Bgage from T S.', 'rule' => ' # BNF Syntax testing rules A -> apple WWWW -> with Bgage -> ->.* B -> bag ->.* -> money W -> WW S -> .shop T -> the the shop -> my brother a never used -> .terminating rule ', ), 4 => array( 'text' => '_1111*11111_', 'rule' => ' ### Unary Multiplication Engine, for testing Markov Algorithm implementations ### By Donal Fellows. # Unary addition engine _+1 -> _1+ 1+1 -> 11+ # Pass for converting from the splitting of multiplication into ordinary # addition 1! -> !1 ,! -> !+ _! -> _ # Unary multiplication by duplicating left side, right side times 1*1 -> x,@y 1x -> xX X, -> 1,1 X1 -> 1X _x -> _X ,x -> ,X y1 -> 1y y_ -> _ # Next phase of applying 1@1 -> x,@y 1@_ -> @_ ,@_ -> !_ ++ -> + # Termination cleanup for addition _1 -> 1 1+_ -> 1 _+_ -> ', ), 5 => array( 'text' => '000000A000000', 'rule' => ' # Turing machine: three-state busy beaver # # state A, symbol 0 => write 1, move right, new state B A0 -> 1B # state A, symbol 1 => write 1, move left, new state C 0A1 -> C01 1A1 -> C11 # state B, symbol 0 => write 1, move left, new state A 0B0 -> A01 1B0 -> A11 # state B, symbol 1 => write 1, move right, new state B B1 -> 1B # state C, symbol 0 => write 1, move left, new state B 0C0 -> B01 1C0 -> B11 # state C, symbol 1 => write 1, move left, halt 0C1 -> H01 1C1 -> H11 ', ), 6 => array( 'text' => '101', 'rule' => ' # Another example extracted from Wikipedia: # http://en.wikipedia.org/wiki/Markov_Algorithm 1 -> 0| |0 -> 0|| 0 -> ', ),
);
foreach ($conf AS $id => $rule) {
echo 'Ruleset ', $id, ' : ', markov($rule['text'], $rule['rule']), PHP_EOL;
}</lang>
- Output:
Ruleset 1 : I bought a bag of apples from my brother. Ruleset 2 : I bought a bag of apples from T shop. Ruleset 3 : I bought a bag of apples with my money from T shop. Ruleset 4 : 11111111111111111111 Ruleset 5 : 00011H1111000 Ruleset 6 : |||||
PicoLisp
<lang PicoLisp>(de markov (File Text)
(use (@A @Z R) (let Rules (make (in File (while (skip "#") (when (match '(@A " " "-" ">" " " @Z) (replace (line) "@" "#")) (link (cons (clip @A) (clip @Z))) ) ) ) ) (setq Text (chop Text)) (pack (loop (NIL (find '((R) (match (append '(@A) (car R) '(@Z)) Text)) Rules ) Text ) (T (= "." (cadr (setq R @))) (append @A (cddr R) @Z) ) (setq Text (append @A (cdr R) @Z)) ) ) ) ) )</lang>
Output:
: (markov "r1" "I bought a B of As from T S.") -> "I bought a bag of apples from my brother." : (markov "r2" "I bought a B of As from T S.") -> "I bought a bag of apples from T shop." : (markov "r3" "I bought a B of As W my Bgage from T S.") -> "I bought a bag of apples with my money from T shop." : (markov "r4" "_1111*11111_") -> "11111111111111111111" : (markov "r5" "000000A000000") -> "00011H1111000"
Prolog
Works with SWI-Prolog and module(library(lambda)).
Module lambda can be found there : http://www.complang.tuwien.ac.at/ulrich/Prolog-inedit/lambda.pl
<lang prolog>:- module('markov.pl', [markov/3, apply_markov/3]).
- - use_module(library(lambda)).
apply_markov(Rules, Sentence, Replacement) :-
maplist(\X^Y^(atom_chars(X, Ch), phrase(markov(Y), Ch, [])), Rules, TmpRules), % comments produce empty rules exclude(=([]), TmpRules, LstRules),
atom_chars(Sentence, L), apply_rules(L, LstRules, R), atom_chars(Replacement, R).
apply_rules(In, Rules, Out ) :-
apply_one_rule(In, Rules, Out1, Keep_On), ( Keep_On = false -> Out = Out1 ; apply_rules(Out1, Rules, Out)).
apply_one_rule(In, [Rule | Rules], Out, Keep_On) :-
extract(Rule, In, Out1, KeepOn), ( KeepOn = false -> Out = Out1, Keep_On = KeepOn ; (KeepOn = stop -> Out = Out1, Keep_On = true ; apply_one_rule(Out1, Rules, Out, Keep_On))).
apply_one_rule(In, [], In, false) .
extract([Pattern, Replace], In, Out, Keep_On) :-
( Replace = [.|Rest] -> R = Rest ; R = Replace), ( (append(Pattern, End, T), append(Deb, T, In)) -> extract([Pattern, Replace], End, NewEnd, _Keep_On), append_3(Deb, R, NewEnd, Out), Keep_On = stop ; Out = In, ( R = Replace -> Keep_On = true ; Keep_On = false)).
append_3(A, B, C, D) :-
append(A, B, T), append(T, C, D).
% creation of the rules markov(A) --> line(A).
line(A) --> text(A), newline.
newline --> ['\n'], newline.
newline --> [].
text([]) --> comment([]). text(A) --> rule(A).
comment([]) --> ['#'], anything.
anything --> [X], {X \= '\n'}, anything. anything --> ['\n']. anything --> [].
rule([A,B]) -->
pattern(A), whitespaces, ['-', '>'], whitespaces, end_rule(B).
pattern([X | R]) --> [X], {X \= '\n'}, pattern(R). pattern([]) --> [].
whitespaces --> ['\t'], whitespace. whitespaces --> [' '], whitespace.
whitespace --> whitespaces. whitespace --> [].
end_rule([.| A]) --> [.], rest_of_rule(A). end_rule(A) --> rest_of_rule(A). end_rule([]) --> [].
rest_of_rule(A) --> replacement(A).
replacement([X | R]) --> [X], {X \= '\n'}, replacement(R). replacement([]) --> []. </lang> Code to test : <lang Prolog>:- use_module('markov.pl').
- - use_module(library(lambda)).
markov :-
maplist(\X^(call(X), nl,nl), [markov_1, markov_2, markov_3, markov_4, markov_5]).
markov_1 :-
A = ['# This rules file is extracted from Wikipedia:', '# http://en.wikipedia.org/wiki/Markov_Algorithm', 'A -> apple', 'B -> bag', 'S -> shop', 'T -> the', 'the shop -> my brother', 'a never used -> .terminating rule'], B = 'I bought a B of As from T S.', apply_markov(A, B, R), writeln(B), writeln(R).
markov_2 :-
A = ['# Slightly modified from the rules on Wikipedia', 'A -> apple', 'B -> bag', 'S -> .shop', 'T -> the', 'the shop -> my brother', 'a never used -> .terminating rule'],
B = 'I bought a B of As from T S.',
apply_markov(A, B, R), writeln(B), writeln(R).
markov_3 :-
A = ['# BNF Syntax testing rules', 'A -> apple', 'WWWW -> with', 'Bgage -> ->.*', 'B -> bag', '->.* -> money', 'W -> WW', 'S -> .shop', 'T -> the', 'the shop -> my brother', 'a never used -> .terminating rule'],
B = 'I bought a B of As W my Bgage from T S.',
apply_markov(A, B, R), writeln(B), writeln(R).
markov_4 :-
A = ['### Unary Multiplication Engine, for testing Markov Algorithm implementations', '### By Donal Fellows.', '# Unary addition engine', '_+1 -> _1+', '1+1 -> 11+', '# Pass for converting from the splitting of multiplication into ordinary', '# addition', '1! -> !1', ',! -> !+', '_! -> _', '# Unary multiplication by duplicating left side, right side times', '1*1 -> x,@y', '1x -> xX', 'X, -> 1,1', 'X1 -> 1X', '_x -> _X', ',x -> ,X', 'y1 -> 1y', 'y_ -> _', '# Next phase of applying', '1@1 -> x,@y', '1@_ -> @_', ',@_ -> !_', '++ -> +', '# Termination cleanup for addition', '_1 -> 1', '1+_ -> 1', '_+_ -> '],
B = '_1111*11111_',
apply_markov(A, B, R), writeln(B), writeln(R).
markov_5 :-
A = ['# Turing machine: three-state busy beaver', '#', '# state A, symbol 0 => write 1, move right, new state B', 'A0 -> 1B', '# state A, symbol 1 => write 1, move left, new state C', '0A1 -> C01', '1A1 -> C11', '# state B, symbol 0 => write 1, move left, new state A', '0B0 -> A01', '1B0 -> A11', '# state B, symbol 1 => write 1, move right, new state B', 'B1 -> 1B', '# state C, symbol 0 => write 1, move left, new state B', '0C0 -> B01', '1C0 -> B11', '# state C, symbol 1 => write 1, move left, halt', '0C1 -> H01', '1C1 -> H11'],
B = '000000A000000', apply_markov(A, B, R), writeln(B), writeln(R).
</lang> Output :
?- markov. I bought a B of As from T S. I bought a bag of apples from my brother. I bought a B of As from T S. I bought a bag of apples from T shop. I bought a B of As W my Bgage from T S. I bought a bag of apples with my money from T shop. _1111*11111_ 11111111111111111111 000000A000000 00011H1111000 true .
PureBasic
The GUI used here allows a ruleset to be loaded from a text file or manually added one rule at a time. Symbol input can be tested anytime by selecting 'Interpret'. <lang PureBasic>Structure mRule
pattern.s replacement.s isTerminal.i
EndStructure
Procedure parseRule(text.s, List rules.mRule())
#tab = 9: #space = 32: #whiteSpace$ = Chr(#space) + Chr(#tab) Protected tLen, cPtr, nChar.c, pEnd, pLast, pattern.s cPtr = 1 If FindString(#whiteSpace$, Left(text, cPtr), 1): ProcedureReturn 0: EndIf ;parse error If Left(text, cPtr) = "#": ProcedureReturn 2: EndIf ;comment skipped tLen = Len(text) Repeat cPtr + 1 If cPtr > tLen: ProcedureReturn 0: EndIf ;parse error nChar = Asc(Mid(text, cPtr, 1)) Select nChar Case #space, #tab Select pEnd Case 0 To 2 pEnd = 1 pLast = cPtr - 1 Case 3 pattern = Left(text, pLast) EndSelect Case '-' If pEnd = 1: pEnd = 2: EndIf Case '>' If pEnd = 2: pEnd = 3: EndIf EndSelect Until pattern <> "" Repeat cPtr + 1 Until Not FindString(#whiteSpace$, Mid(text, cPtr, 1), 1) Protected isTerminal If Mid(text, cPtr, 1) = "." isTerminal = #True: cPtr + 1 EndIf LastElement(rules()): AddElement(rules()) rules()\pattern = pattern rules()\replacement = Right(text, tLen - cPtr + 1) rules()\isTerminal = isTerminal ProcedureReturn 1 ;processed rule
EndProcedure
Procedure.s interpretMarkov(text.s, List rules.mRule())
Repeat madeReplacement = #False ForEach rules() If FindString(text, rules()\pattern, 1) text = ReplaceString(text, rules()\pattern, rules()\replacement) madeReplacement = #True: isFinished = rules()\isTerminal Break EndIf Next Until Not madeReplacement Or isFinished ProcedureReturn text
EndProcedure
Procedure addRule(text.s, List rules.mRule())
Protected result = parseRule(text, rules()) Select result Case 0: AddGadgetItem(7, -1, "Invalid rule: " + #DQUOTE$ + text + #DQUOTE$) Case 1: AddGadgetItem(7, -1, "Added: " + #DQUOTE$ + text + #DQUOTE$) Case 2: AddGadgetItem(7, -1, "Comment: " + #DQUOTE$ + text + #DQUOTE$) EndSelect
EndProcedure
OpenWindow(0, 0, 0, 350, 300, "Markov Algorithm Interpreter", #PB_Window_SystemMenu) ButtonGadget(0, 45, 10, 75, 20, "Load Ruleset") ButtonGadget(1, 163, 10, 65, 20, "Add Rule") ButtonGadget(2, 280, 10, 65, 20, "Interpret") TextGadget(3, 5, 40, 30, 20, "Input:") StringGadget(4, 45, 40, 300, 20,"") TextGadget(5, 5, 100, 35, 20, "Output:") ButtonGadget(6, 160, 70, 70, 20, "Clear Output") EditorGadget(7, 45, 100, 300, 195, #PB_Editor_ReadOnly)
NewList rules.mRule() Define event, isDone, text.s, result, file.s Repeat
event = WaitWindowEvent() Select event Case #PB_Event_Gadget Select EventGadget() Case 0 Define file.s, rule.s file = OpenFileRequester("Select rule set", "*.txt", "Text (*.txt)|*.txt", 0) If file ClearList(rules()) ReadFile(0, file) While Not(Eof(0)) addRule(ReadString(0), rules()) Wend AddGadgetItem(7, -1, "Loaded " + Str(ListSize(rules())) + " rules."): AddGadgetItem(7, -1, "") EndIf Case 1 addRule(GetGadgetText(4), rules()) Case 2 text = GetGadgetText(4): AddGadgetItem(7, -1, "Interpret: " + #DQUOTE$ + text + #DQUOTE$) AddGadgetItem(7, -1, "Result: " + #DQUOTE$ + interpretMarkov(text, rules()) + #DQUOTE$): AddGadgetItem(7, -1, "") Case 6 ClearGadgetItems(7) EndSelect Case #PB_Event_CloseWindow isDone = #True EndSelect
Until isDone </lang> Sample output from loading Ruleset 1 and interpreting a symbol:
Comment: "# This rules file is extracted from Wikipedia:" Comment: "# http://en.wikipedia.org/wiki/Markov_Algorithm" Added: "A -> apple" Added: "B -> bag" Added: "S -> shop" Added: "T -> the" Added: "the shop -> my brother" Added: "a never used -> .terminating rule" Loaded 6 rules. Interpret: "I bought a B of As from T S." Result: "I bought a bag of apples from my brother."
Python
The example uses a regexp to parse the syntax of the grammar. This regexp is multi-line and verbose, and uses named groups to aid in understanding the regexp and to allow more meaningful group names to be used when extracting the replacement data from the grammars in function extractreplacements
.
The example gains flexibility by not being tied to specific files. The functions may be imported into other programs which then can provide textual input from their sources without the need to pass 'file handles' around. <lang python>import re
def extractreplacements(grammar):
return [ (matchobj.group('pat'), matchobj.group('repl'), bool(matchobj.group('term'))) for matchobj in re.finditer(syntaxre, grammar) if matchobj.group('rule')]
def replace(text, replacements):
while True: for pat, repl, term in replacements: if pat in text: text = text.replace(pat, repl, 1) if term: return text break else: return text
syntaxre = r"""(?mx) ^(?:
(?: (?P<comment> \# .* ) ) | (?: (?P<blank> \s* ) (?: \n | $ ) ) | (?: (?P<rule> (?P<pat> .+? ) \s+ -> \s+ (?P<term> \.)? (?P<repl> .+) ) )
)$ """
grammar1 = """\
- This rules file is extracted from Wikipedia:
- http://en.wikipedia.org/wiki/Markov_Algorithm
A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule """
grammar2 = \
- Slightly modified from the rules on Wikipedia
A -> apple B -> bag S -> .shop T -> the the shop -> my brother a never used -> .terminating rule
grammar3 = \
- BNF Syntax testing rules
A -> apple WWWW -> with Bgage -> ->.* B -> bag ->.* -> money W -> WW S -> .shop T -> the the shop -> my brother a never used -> .terminating rule
grammar4 = \
- Unary Multiplication Engine, for testing Markov Algorithm implementations
- By Donal Fellows.
- Unary addition engine
_+1 -> _1+ 1+1 -> 11+
- Pass for converting from the splitting of multiplication into ordinary
- addition
1! -> !1 ,! -> !+ _! -> _
- Unary multiplication by duplicating left side, right side times
1*1 -> x,@y 1x -> xX X, -> 1,1 X1 -> 1X _x -> _X ,x -> ,X y1 -> 1y y_ -> _
- Next phase of applying
1@1 -> x,@y 1@_ -> @_ ,@_ -> !_ ++ -> +
- Termination cleanup for addition
_1 -> 1 1+_ -> 1 _+_ ->
grammar5 = \
- Turing machine: three-state busy beaver
- state A, symbol 0 => write 1, move right, new state B
A0 -> 1B
- state A, symbol 1 => write 1, move left, new state C
0A1 -> C01 1A1 -> C11
- state B, symbol 0 => write 1, move left, new state A
0B0 -> A01 1B0 -> A11
- state B, symbol 1 => write 1, move right, new state B
B1 -> 1B
- state C, symbol 0 => write 1, move left, new state B
0C0 -> B01 1C0 -> B11
- state C, symbol 1 => write 1, move left, halt
0C1 -> H01 1C1 -> H11
text1 = "I bought a B of As from T S."
text2 = "I bought a B of As W my Bgage from T S."
text3 = '_1111*11111_'
text4 = '000000A000000'
if __name__ == '__main__':
assert replace(text1, extractreplacements(grammar1)) \ == 'I bought a bag of apples from my brother.' assert replace(text1, extractreplacements(grammar2)) \ == 'I bought a bag of apples from T shop.' # Stretch goals assert replace(text2, extractreplacements(grammar3)) \ == 'I bought a bag of apples with my money from T shop.' assert replace(text3, extractreplacements(grammar4)) \ == '11111111111111111111' assert replace(text4, extractreplacements(grammar5)) \ == '00011H1111000'</lang>
Racket
The Markov algorithm interpreter
The Markov-algorithm for a set of rules returns a function which maps from a string to string and can be used as a first-class object. Rules are represented by abstract data structures.
<lang racket>
- lang racket
(struct -> (A B)) (struct ->. (A B))
(define ((Markov-algorithm . rules) initial-string)
(let/cc stop ; rewriting rules (define (rewrite rule str) (match rule [(-> a b) (cond [(replace a str b) => apply-rules] [else str])] [(->. a b) (cond [(replace a str b) => stop] [else str])])) ; the cycle through rewriting rules (define (apply-rules s) (foldl rewrite s rules)) ; the result is a fixed point of rewriting procedure (fixed-point apply-rules initial-string)))
- replaces the first substring A to B in a string s
(define (replace A s B)
(and (regexp-match? (regexp-quote A) s) (regexp-replace (regexp-quote A) s B)))
- Finds the least fixed-point of a function
(define (fixed-point f x0)
(let loop ([x x0] [fx (f x0)]) (if (equal? x fx) fx (loop fx (f fx)))))
</lang>
Example of use:
<lang racket> > (define MA
(Markov-algorithm (-> "A" "apple") (-> "B" "bag") (->. "S" "shop") (-> "T" "the") (-> "the shop" "my brother") (->. "a never used" "terminating rule")))
> (MA "I bought a B of As from T S.") "I bought a bag of apples from T shop." </lang>
The source reader
To read from a file just replace with-input-from-string ==> with-input-from-file.
<lang racket>
- the reader
(define (read-rules source)
(with-input-from-string source (λ () (for*/list ([line (in-lines)] #:unless (should-be-skipped? line)) (match line [(rx-split A "blank:->blank:[.]" B) (->. A B)] [(rx-split A "blank:->blank:" B) (-> A B)])))))
- the new pattern for the match form
(define-match-expander rx-split
(syntax-rules () [(rx-split A rx B) (app (λ (s) (regexp-split (pregexp rx) s)) (list A B))]))
- skip empty lines and comments
(define (should-be-skipped? line)
(or (regexp-match? #rx"^#.*" line) (regexp-match? #px"^blank:*$" line)))
(define (read-Markov-algorithm source)
(apply Markov-algorithm (read-rules source)))
</lang>
Examples:
<lang racket> (define R3 (read-Markov-algorithm "
- BNF Syntax testing rules
A -> apple WWWW -> with Bgage -> ->.* B -> bag ->.* -> money W -> WW S -> .shop T -> the the shop -> my brother a never used -> .terminating rule"))
(define R4
(read-Markov-algorithm "
- Unary Multiplication Engine, for testing Markov Algorithm implementations
- By Donal Fellows.
- Unary addition engine
_+1 -> _1+ 1+1 -> 11+
- Pass for converting from the splitting of multiplication into ordinary
- addition
1! -> !1 ,! -> !+ _! -> _
- Unary multiplication by duplicating left side, right side times
1*1 -> x,@y 1x -> xX X, -> 1,1 X1 -> 1X _x -> _X ,x -> ,X y1 -> 1y y_ -> _
- Next phase of applying
1@1 -> x,@y 1@_ -> @_ ,@_ -> !_ ++ -> +
- Termination cleanup for addition
_1 -> 1 1+_ -> 1 _+_ -> "))
(define R5
(read-Markov-algorithm "
- Turing machine: three-state busy beaver
- state A, symbol 0 => write 1, move right, new state B
A0 -> 1B
- state A, symbol 1 => write 1, move left, new state C
0A1 -> C01 1A1 -> C11
- state B, symbol 0 => write 1, move left, new state A
0B0 -> A01 1B0 -> A11
- state B, symbol 1 => write 1, move right, new state B
B1 -> 1B
- state C, symbol 0 => write 1, move left, new state B
0C0 -> B01 1C0 -> B11
- state C, symbol 1 => write 1, move left, halt
0C1 -> H01 1C1 -> H11")) </lang>
<lang racket> > (R3 "I bought a B of As W my Bgage from T S.") "I bought a bag of apples with my money from T shop."
> (R4 "_1111*11111_") "11111111111111111111"
> (R5 "000000A000000") "00011H1111000" </lang>
Raku
(formerly Perl 6) Run this without arguments and it will scan the cwd for rules.* files and their corresponding test.*.
Run it with two filenames or one filename and some text to run a rulefile on the file contents or the given text.
Add --verbose to see the replacements step-by-step.
<lang perl6>grammar Markov {
token TOP { ^ [^^ [<rule> | <comment>] $$ [\n|$]]* $ { make $<rule>>>.ast } } token comment { <before ^^> '#' \N* { make Nil } } token ws { [' '|\t]* } rule rule { <before ^^>$<pattern>=[\N+?] '->' $<terminal>=[\.]?$<replacement>=[\N*] { make {:pattern($<pattern>.Str), :replacement($<replacement>.Str), :terminal($<terminal>.Str eq ".")} } }
}
sub run(:$ruleset, :$start_value, :$verbose?) {
my $value = $start_value; my @rules = Markov.parse($ruleset).ast.list; loop { my $beginning = $value; for @rules { my $prev = $value; $value = $value.subst(.<pattern>, .<replacement>); say $value if $verbose && $value ne $prev; return $value if .<terminal>; last if $value ne $prev; } last if $value eq $beginning; } return $value;
}
multi sub MAIN(Bool :$verbose?) {
my @rulefiles = dir.grep(/rules.+/).sort; for @rulefiles -> $rulefile { my $testfile = $rulefile.subst("rules", "test"); my $start_value = (try slurp($testfile).trim-trailing) // prompt("please give a start value: "); my $ruleset = slurp($rulefile); say $start_value; say run(:$ruleset, :$start_value, :$verbose); say ; }
}
multi sub MAIN(Str $rulefile where *.IO.f, Str $input where *.IO.f, Bool :$verbose?) {
my $ruleset = slurp($rulefile); my $start_value = slurp($input).trim-trailing; say "starting with: $start_value"; say run(:$ruleset, :$start_value, :$verbose);
}
multi sub MAIN(Str $rulefile where *.IO.f, *@pieces, Bool :$verbose?) {
my $ruleset = slurp($rulefile); my $start_value = @pieces.join(" "); say "starting with: $start_value"; say run(:$ruleset, :$start_value, :$verbose);
}</lang>
REXX
Code was added to the REXX example to optionally list the contents of the ruleset and/or the Markov entries.
Also, blank lines in the ruleset were treated as comments.
<lang rexx>/*REXX program executes a Markov algorithm(s) against specified entries. */
parse arg low high . /*allows which ruleset to process. */
if low== | low=="," then low=1 /*Not specified? Then use the default.*/
if high== | high=="," then high=6 /* " " " " " " */
tellE= low<0; tellR= high<0 /*flags: used to display file contents.*/
call readEntry
do j=abs(low) to abs(high) /*process each of these rulesets. */ call readRules j /*read a particular ruleset. */ call execRules j /*execute " " " */ say 'result for ruleset' j "───►" !.j end /*j*/
exit /*stick a fork in it, we're all done. */ /*──────────────────────────────────────────────────────────────────────────────────────*/ execRules: parse arg q .; if tellE | tellR then say /*show a blank line?*/
do f=1 do k=1 while @.k\==; if left(@.k, 1)=='#' | @.k= then iterate parse var @.k a ' ->' b /*obtain the A & B parts from rule.*/ a=strip(a); b=strip(b) /*strip leading and/or trailing blanks.*/ fullstop= left(b, 1)==. /*is this a "fullstop" rule? 1≡yes */ if fullstop then b=substr(b, 2) /*purify the B part of the rule. */ old=!.q /*remember the value before the change.*/ !.q=changestr(a, !.q, b) /*implement the ruleset change. */ if fullstop then if old\==!.q then return /*should we stop? */ if old\==!.q then iterate f /*Has Entry changed? Then start over.*/ end /*k*/ return end /*f*/ return
/*──────────────────────────────────────────────────────────────────────────────────────*/ readEntry: eFID= 'MARKOV.ENT'; if tellE then say /*show a blank line?*/
!.= /*placeholder for all the test entries.*/ do e=1 while lines(eFID)\==0 /*read the input file until End-Of-File*/ !.e=linein(eFID); if tellE then say 'test entry' e "───►" !.e end /*e*/ /* [↑] read and maybe echo the entry. */ return
/*──────────────────────────────────────────────────────────────────────────────────────*/ readRules: parse arg ? .; rFID= 'MARKOV_R.'?; if tellR then say /*show a blank line?*/
@.= /*placeholder for all the Markov rules.*/ do r=1 while lines(rFID)\==0 /*read the input file until End-Of-File*/ @.r=linein(rFID); if tellR then say 'ruleSet' ?"."left(r,4) '───►' @.r end /*r*/ /* [↑] read and maybe echo the rule. */ return</lang>
Some older REXXes don't have a changestr BIF, so one is included here ──► CHANGESTR.REX.
- output when using the default input and files:
result for ruleset 1 ───► I bought a B of As from T S. result for ruleset 2 ───► I bought a bag of apples from T shop. result for ruleset 3 ───► I bought a bag of apples with my money from T shop. result for ruleset 4 ───► 11111111111111111111 result for ruleset 5 ───► 00011H1111000 result for ruleset 6 ───► |||||
- Ruleset 6 is:
# Rewrite binary numbers to their unary value (| bars). # I.E.: 101 [base 2] will be converted to 5 bars. #────────────────────────────────────────────────────── |0 -> 0|| 1 -> 0| 0 ->
Ruby
<lang Ruby>def setup(ruleset)
ruleset.each_line.inject([]) do |rules, line| if line =~ /^\s*#/ rules elsif line =~ /^(.+)\s+->\s+(\.?)(.*)$/ rules << [$1, $3, $2 != ""] else raise "Syntax error: #{line}" end end
end
def morcov(ruleset, input_data)
rules = setup(ruleset) while (matched = rules.find { |match, replace, term| input_data[match] and input_data.sub!(match, replace) }) and !matched[2] end input_data
end</lang>
Test: <lang Ruby>ruleset1 = <<EOS
- This rules file is extracted from Wikipedia:
- http://en.wikipedia.org/wiki/Markov_Algorithm
A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule EOS
puts morcov(ruleset1, "I bought a B of As from T S.")
ruleset2 = <<EOS
- Slightly modified from the rules on Wikipedia
A -> apple B -> bag S -> .shop T -> the the shop -> my brother a never used -> .terminating rule EOS
puts morcov(ruleset2, "I bought a B of As from T S.")
ruleset3 = <<EOS
- BNF Syntax testing rules
A -> apple WWWW -> with Bgage -> ->.* B -> bag ->.* -> money W -> WW S -> .shop T -> the the shop -> my brother a never used -> .terminating rule EOS
puts morcov(ruleset3, "I bought a B of As W my Bgage from T S.")
ruleset4 = <<EOS
- Unary Multiplication Engine, for testing Markov Algorithm implementations
- By Donal Fellows.
- Unary addition engine
_+1 -> _1+ 1+1 -> 11+
- Pass for converting from the splitting of multiplication into ordinary
- addition
1! -> !1 ,! -> !+ _! -> _
- Unary multiplication by duplicating left side, right side times
1*1 -> x,@y 1x -> xX X, -> 1,1 X1 -> 1X _x -> _X ,x -> ,X y1 -> 1y y_ -> _
- Next phase of applying
1@1 -> x,@y 1@_ -> @_ ,@_ -> !_ ++ -> +
- Termination cleanup for addition
_1 -> 1 1+_ -> 1 _+_ -> EOS
puts morcov(ruleset4, "_1111*11111_")
ruleset5 = <<EOS
- Turing machine: three-state busy beaver
- state A, symbol 0 => write 1, move right, new state B
A0 -> 1B
- state A, symbol 1 => write 1, move left, new state C
0A1 -> C01 1A1 -> C11
- state B, symbol 0 => write 1, move left, new state A
0B0 -> A01 1B0 -> A11
- state B, symbol 1 => write 1, move right, new state B
B1 -> 1B
- state C, symbol 0 => write 1, move left, new state B
0C0 -> B01 1C0 -> B11
- state C, symbol 1 => write 1, move left, halt
0C1 -> H01 1C1 -> H11 EOS
puts morcov(ruleset5, "000000A000000")</lang>
- Output:
I bought a bag of apples from my brother. I bought a bag of apples from T shop. I bought a bag of apples with my money from T shop. 11111111111111111111 00011H1111000
Rust
<lang rust>use std::str::FromStr;
- [derive(Clone, Debug)]
pub struct Rule {
pub pat: String, pub rep: String, pub terminal: bool,
}
impl Rule {
pub fn new(pat: String, rep: String, terminal: bool) -> Self { Self { pat, rep, terminal } }
pub fn applicable_range(&self, input: impl AsRef<str>) -> Option<std::ops::Range<usize>> { input .as_ref() .match_indices(&self.pat) .next() .map(|(start, slice)| start..start + slice.len()) }
pub fn apply(&self, s: &mut String) -> bool { self.applicable_range(s.as_str()).map_or(false, |range| { s.replace_range(range, &self.rep); true }) }
}
impl FromStr for Rule {
type Err = String;
fn from_str(s: &str) -> Result<Self, Self::Err> { let mut split = s.splitn(2, " -> "); let pat = split.next().ok_or_else(|| s.to_string())?; let rep = split.next().ok_or_else(|| s.to_string())?;
let pat = pat.to_string(); if rep.starts_with('.') { Ok(Self::new(pat, rep[1..].to_string(), true)) } else { Ok(Self::new(pat, rep.to_string(), false)) } }
}
- [derive(Clone, Debug)]
pub struct Rules {
rules: Vec<Rule>,
}
impl Rules {
pub fn new(rules: Vec<Rule>) -> Self { Self { rules } }
pub fn apply(&self, s: &mut String) -> Option<&Rule> { self.rules .iter() .find(|rule| rule.apply(s)) }
pub fn execute(&self, mut buffer: String) -> String { while let Some(rule) = self.apply(&mut buffer) { if rule.terminal { break; } }
buffer }
}
impl FromStr for Rules {
type Err = String;
fn from_str(s: &str) -> Result<Self, Self::Err> { let mut rules = Vec::new();
for line in s.lines().filter(|line| !line.starts_with('#')) { rules.push(line.parse::<Rule>()?); }
Ok(Rules::new(rules)) }
}
- [cfg(test)]
mod tests {
use super::Rules;
#[test] fn case_01() -> Result<(), String> { let input = "I bought a B of As from T S."; let rules = "\
- This rules file is extracted from Wikipedia:
- http://en.wikipedia.org/wiki/Markov_Algorithm
A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule";
assert_eq!( rules.parse::<Rules>()?.execute(input.to_string()), "I bought a bag of apples from my brother." );
Ok(()) }
#[test] fn case_02() -> Result<(), String> { let input = "I bought a B of As from T S."; let rules = "\
- Slightly modified from the rules on Wikipedia
A -> apple B -> bag S -> .shop T -> the the shop -> my brother a never used -> .terminating rule";
assert_eq!( rules.parse::<Rules>()?.execute(input.to_string()), "I bought a bag of apples from T shop." );
Ok(()) }
#[test] fn case_03() -> Result<(), String> { let input = "I bought a B of As W my Bgage from T S."; let rules = "\
- BNF Syntax testing rules
A -> apple WWWW -> with Bgage -> ->.* B -> bag ->.* -> money W -> WW S -> .shop T -> the the shop -> my brother a never used -> .terminating rule";
assert_eq!( rules.parse::<Rules>()?.execute(input.to_string()), "I bought a bag of apples with my money from T shop." );
Ok(()) }
#[test] fn case_04() -> Result<(), String> { let input = "_1111*11111_"; let rules = "\
- Unary Multiplication Engine, for testing Markov Algorithm implementations
- By Donal Fellows.
- Unary addition engine
_+1 -> _1+ 1+1 -> 11+
- Pass for converting from the splitting of multiplication into ordinary
- addition
1! -> !1 ,! -> !+ _! -> _
- Unary multiplication by duplicating left side, right side times
1*1 -> x,@y 1x -> xX X, -> 1,1 X1 -> 1X _x -> _X ,x -> ,X y1 -> 1y y_ -> _
- Next phase of applying
1@1 -> x,@y 1@_ -> @_ ,@_ -> !_ ++ -> +
- Termination cleanup for addition
_1 -> 1 1+_ -> 1 _+_ -> ";
assert_eq!( rules.parse::<Rules>()?.execute(input.to_string()), "11111111111111111111" );
Ok(()) }
#[test] fn case_05() -> Result<(), String> { let input = "000000A000000"; let rules = "\
- Turing machine: three-state busy beaver
- state A, symbol 0 => write 1, move right, new state B
A0 -> 1B
- state A, symbol 1 => write 1, move left, new state C
0A1 -> C01 1A1 -> C11
- state B, symbol 0 => write 1, move left, new state A
0B0 -> A01 1B0 -> A11
- state B, symbol 1 => write 1, move right, new state B
B1 -> 1B
- state C, symbol 0 => write 1, move left, new state B
0C0 -> B01 1C0 -> B11
- state C, symbol 1 => write 1, move left, halt
0C1 -> H01 1C1 -> H11";
assert_eq!( rules.parse::<Rules>()?.execute(input.to_string()), "00011H1111000" );
Ok(()) }
} </lang>
Scala
<lang scala>import scala.io.Source
object MarkovAlgorithm {
val RulePattern = """(.*?)\s+->\s+(\.?)(.*)""".r val CommentPattern = """#.*|\s*""".r def rule(line: String) = line match { case CommentPattern() => None case RulePattern(pattern, terminal, replacement) => Some(pattern, replacement, terminal == ".") case _ => error("Syntax error on line "+line) } def main(args: Array[String]) { if (args.size != 2 ) { println("Syntax: MarkovAlgorithm inputFile inputPattern") exit(1) } val rules = (Source fromPath args(0) getLines () map rule).toList.flatten def algorithm(input: String): String = rules find (input contains _._1) match { case Some((pattern, replacement, true)) => input replaceFirst ("\\Q"+pattern+"\\E", replacement) case Some((pattern, replacement, false)) => algorithm(input replaceFirst ("\\Q"+pattern+"\\E", replacement)) case None => input }
println(args(1)) println(algorithm(args(1))) }
}</lang>
Script-style, and more concise:
<lang scala>import scala.io.Source
if (argv.size != 2 ) error("Syntax: MarkovAlgorithm inputFile inputPattern")
val rulePattern = """(.*?)\s+->\s+(\.?)(.*)""".r val isComment = (_: String) matches "#.*|\\s*" val rules = Source fromPath args(0) getLines () filterNot isComment map (rulePattern unapplySeq _ get) toList;
def algorithm(input: String): String = rules find (input contains _.head) match {
case Some(Seq(pattern, ".", replacement)) => input replaceFirst ("\\Q"+pattern+"\\E", replacement) case Some(Seq(pattern, "", replacement)) => algorithm(input replaceFirst ("\\Q"+pattern+"\\E", replacement)) case None => input
}
println(argv(1)) println(algorithm(argv(1)))</lang>
Sample outputs:
C:\>scala MarkovAlgorithm ruleset1.txt "I bought a B of As from T S." I bought a B of As from T S. I bought a bag of apples from my brother. C:\>scala MarkovAlgorithm ruleset2.txt "I bought a B of As from T S." I bought a B of As from T S. I bought a bag of apples from T shop. C:\>scala MarkovAlgorithm ruleset3.txt "I bought a B of As W my Bgage from T S." I bought a B of As W my Bgage from T S. I bought a bag of apples with my money from T shop. C:\>scala MarkovAlgorithm ruleset4.txt "_1111*11111_" _1111*11111_ 11111111111111111111
The script is called much in the same way, but with the ".scala" extension added.
Scheme
The following implementation uses several string-related procedures provided by SRFI-13 [1].
<lang scheme> (define split-into-lines
(lambda (str) (let loop ((index 0) (result '())) (let ((next-index (string-index str #\newline index))) (if next-index (loop (+ next-index 1) (cons (substring str index next-index) result)) (reverse (cons (substring str index) result)))))))
(define parse-rules
(lambda (str) (let loop ((rules (split-into-lines str)) (result '())) (if (null? rules) (reverse result) (let ((rule (car rules))) (loop (cdr rules) (if (or (string=? rule "") (eq? (string-ref rule 0) #\#)) result (cons (let ((index (string-contains rule "->" 1))) (list (string-trim-right (substring rule 0 index)) (string-trim (substring rule (+ index 2))))) result))))))))
(define apply-rules
(lambda (str rules) (let loop ((remaining rules) (result str)) (if (null? remaining) result (let* ((rule (car remaining)) (pattern (car rule)) (replacement (cadr rule)) (start (string-contains result pattern))) (if start (if (eq? #\. (string-ref replacement 0)) (string-replace result replacement start (+ start (string-length pattern)) 1) (apply-rules (string-replace result replacement start (+ start (string-length pattern))) rules)) (loop (cdr remaining) result)))))))
</lang>
SequenceL
<lang sequenceL> import <Utilities/Sequence.sl>;
Rule ::= ( pattern : char(1),
replacement : char(1), terminal : bool);
ReplaceResult ::= (newString : char(1), wasReplaced : bool);
main(args(2)) := markov(createRule(split(args[1], '\n')), 1, args[2]);
createRule(line(1)) :=
let containsComments := firstIndexOf(line, '#'); removedComments := line when containsComments = 0 else line[1 ... containsComments - 1];
arrowLocation := startOfArrow(removedComments, 1); lhs := removedComments[1 ... arrowLocation-1]; rhs := removedComments[arrowLocation + 4 ... size(removedComments)]; isTerminal := size(rhs) > 0 and rhs[1] = '.'; in (pattern : lhs, replacement : rhs[2 ... size(rhs)] when isTerminal else rhs, terminal : isTerminal) when size(removedComments) > 0 and arrowLocation /= -1;
startOfArrow(line(1), n) :=
-1 when n > size(line) - 3 else n when (line[n]=' ' or line[n]='\t') and line[n+1] = '-' and line[n+2] = '>' and (line[n+3]=' ' or line[n+3]='\t') else startOfArrow(line, n+1);
markov(rules(1), n, input(1)) :=
let replaced := replaceSubString(input, rules[n].pattern, rules[n].replacement, 1); in input when n > size(rules) else replaced.newString when replaced.wasReplaced and rules[n].terminal else markov(rules, 1, replaced.newString) when replaced.wasReplaced else markov(rules, n+1, input);
replaceSubString(str(1), original(1), new(1), n) :=
(newString : str, wasReplaced : false) when n > size(str) - size(original) + 1 else (newString : str[1 ... n - 1] ++ new ++ str[n + size(original) ... size(str)], wasReplaced : true) when equalList(str[n ... n + size(original) - 1], original) else replaceSubString(str, original, new, n + 1);
</lang>
SNOBOL4
Note that the run-time data is immediately after the "end" label. This works with CSNOBOL4, on a Unix (or Unix-like) platform. The Markov rules are actually compiled into the program after parsing, and are then directly executed (self-modifying code). <lang SNOBOL4>
- !/bin/sh
exec "snobol4" "-r" "$0" "$@"
define('repl(s1,s2,s3)c,t,findc') :(repl_end)
repl s2 len(1) . c = :f(freturn)
findc = break(c) . t len(1) s2 = pos(0) s2
repl_1 s1 findc = :f(repl_2)
s1 s2 = :f(repl_3) repl = repl t s3 :(repl_1)
repl_3 repl = repl t c :(repl_1) repl_2 repl = repl s1 :(return) repl_end
define('quote(s)q,qq') :(quote_end)
quote q = "'"; qq = '"'
quote = q repl(s, q, q ' ' qq q qq ' ' q) q :(return)
quote_end
whitespace = span(' ' char(9))
top r = 0 read s = input :f(end)
s pos(0) 'ENDRULE' rpos(0) :s(interp) s pos(0) '#' :s(read) pattern =; replacement =; term = s arb . pattern whitespace '->' whitespace
+ ('.' | ) . term arb . replacement rpos(0) :f(syntax)
r = r + 1 f = ident(term, '.') ' :(done)' f = ident(term) ' :f(rule' r + 1 ')s(rule1)' c = 'rule' r ' s ' quote(pattern) ' = ' quote(replacement) f code(c) :s(read) output = 'rule: ' s ' generates code ' c ' in error' :(end)
syntax output = 'rule: ' s ' in error' :(read) interp code('rule' r + 1 ' :(done)') go s = input :f(end)
s pos(0) 'END' rpos(0) :s(top)f(rule1)
done output = s :(go) end
- This rules file is extracted from Wikipedia:
- http://en.wikipedia.org/wiki/Markov_Algorithm
A -> apple B -> bag S -> shop T -> the the shop -> my brother a never used -> .terminating rule ENDRULE I bought a B of As from T S. END
- Slightly modified from the rules on Wikipedia
A -> apple B -> bag S -> .shop T -> the the shop -> my brother a never used -> .terminating rule ENDRULE I bought a B of As from T S. END
- BNF Syntax testing rules
A -> apple WWWW -> with Bgage -> ->.* B -> bag ->.* -> money W -> WW S -> .shop T -> the the shop -> my brother a never used -> .terminating rule ENDRULE I bought a B of As W my Bgage from T S. END
- Unary Multiplication Engine, for testing Markov Algorithm implementations
- By Donal Fellows.
- Unary addition engine
_+1 -> _1+ 1+1 -> 11+
- Pass for converting from the splitting of multiplication into ordinary
- addition
1! -> !1 ,! -> !+ _! -> _
- Unary multiplication by duplicating left side, right side times
1*1 -> x,@y 1x -> xX X, -> 1,1 X1 -> 1X _x -> _X ,x -> ,X y1 -> 1y y_ -> _
- Next phase of applying
1@1 -> x,@y 1@_ -> @_ ,@_ -> !_ ++ -> +
- Termination cleanup for addition
_1 -> 1 1+_ -> 1 _+_ -> ENDRULE _1111*11111_ END
- Turing machine: three-state busy beaver
- state A, symbol 0 => write 1, move right, new state B
A0 -> 1B
- state A, symbol 1 => write 1, move left, new state C
0A1 -> C01 1A1 -> C11
- state B, symbol 0 => write 1, move left, new state A
0B0 -> A01 1B0 -> A11
- state B, symbol 1 => write 1, move right, new state B
B1 -> 1B
- state C, symbol 0 => write 1, move left, new state B
0C0 -> B01 1C0 -> B11
- state C, symbol 1 => write 1, move left, halt
0C1 -> H01 1C1 -> H11 ENDRULE 000000A000000 END </lang>
Swift
<lang swift>import Foundation
func setup(ruleset: String) -> [(String, String, Bool)] {
return ruleset.componentsSeparatedByCharactersInSet(NSCharacterSet.newlineCharacterSet()) .filter { $0.rangeOfString("^s*#", options: .RegularExpressionSearch) == nil } .reduce([(String, String, Bool)]()) { rules, line in let regex = try! NSRegularExpression(pattern: "^(.+)\\s+->\\s+(\\.?)(.*)$", options: .CaseInsensitive) guard let match = regex.firstMatchInString(line, options: .Anchored, range: NSMakeRange(0, line.characters.count)) else { return rules } return rules + [( (line as NSString).substringWithRange(match.rangeAtIndex(1)), (line as NSString).substringWithRange(match.rangeAtIndex(3)), (line as NSString).substringWithRange(match.rangeAtIndex(2)) != "" )] }
}
func markov(ruleset: String, var input: String) -> String {
let rules = setup(ruleset) var terminate = false while !terminate { guard let i = rules.indexOf ({ if let range = input.rangeOfString($0.0) { input.replaceRange(range, with: $0.1) return true } return false }) else { break } terminate = rules[i].2 } return input
}
let tests: [(ruleset: String, input: String)] = [
("# This rules file is extracted from Wikipedia:\n# http://en.wikipedia.org/wiki/Markov_Algorithm\nA -> apple\nB -> bag\nS -> shop\nT -> the\nthe shop -> my brother\na never used -> .terminating rule", "I bought a B of As from T S."), ("# Slightly modified from the rules on Wikipedia\nA -> apple\nB -> bag\nS -> .shop\nT -> the\nthe shop -> my brother\na never used -> .terminating rule", "I bought a B of As from T S."), ("# BNF Syntax testing rules\nA -> apple\nWWWW -> with\nBgage -> ->.*\nB -> bag\n->.* -> money\nW -> WW\nS -> .shop\nT -> the\nthe shop -> my brother\na never used -> .terminating rule", "I bought a B of As W my Bgage from T S."), ("### Unary Multiplication Engine, for testing Markov Algorithm implementations\n### By Donal Fellows.\n# Unary addition engine\n_+1 -> _1+\n1+1 -> 11+\n# Pass for converting from the splitting of multiplication into ordinary\n# addition\n1! -> !1\n,! -> !+\n_! -> _\n# Unary multiplication by duplicating left side, right side times\n1*1 -> x,@y\n1x -> xX\nX, -> 1,1\nX1 -> 1X\n_x -> _X\n,x -> ,X\ny1 -> 1y\ny_ -> _\n# Next phase of applying\n1@1 -> x,@y\n1@_ -> @_\n,@_ -> !_\n++ -> +\n# Termination cleanup for addition\n_1 -> 1\n1+_ -> 1\n_+_ ->", "_1111*11111_"), ("# Turing machine: three-state busy beaver\n#\n# state A, symbol 0 => write 1, move right, new state B\nA0 -> 1B\n# state A, symbol 1 => write 1, move left, new state C\n0A1 -> C01\n1A1 -> C11\n# state B, symbol 0 => write 1, move left, new state A\n0B0 -> A01\n1B0 -> A11\n# state B, symbol 1 => write 1, move right, new state B\nB1 -> 1B\n# state C, symbol 0 => write 1, move left, new state B\n0C0 -> B01\n1C0 -> B11\n# state C, symbol 1 => write 1, move left, halt\n0C1 -> H01\n1C1 -> H11", "000000A000000")
]
for (index, test) in tests.enumerate() {
print("\(index + 1):", markov(test.ruleset, input: test.input))
}
</lang>
- Output:
1: I bought a bag of apples from my brother. 2: I bought a bag of apples from T shop. 3: I bought a bag of apples with my money from T shop. 4: 11111111111111111111 5: 00011H1111000
Tcl
<lang tcl>package require Tcl 8.5 if {$argc < 3} {error "usage: $argv0 ruleFile inputFile outputFile"} lassign $argv ruleFile inputFile outputFile
- Read the file of rules
set rules {} set f [open $ruleFile] foreach line [split [read $f] \n[close $f]] {
if {[string match "#*" $line] || $line eq ""} continue if {[regexp {^(.+)\s+->\s+(\.?)(.*)$} $line -> from final to]} { lappend rules $from $to [string compare "." $final] [string length $from] } else { error "Syntax error: \"$line\"" }
}
- Apply the rules
set f [open $inputFile] set out [open $outputFile w] foreach line [split [read $f] \n[close $f]] {
set any 1 while {$any} { set any 0 foreach {from to more fl} $rules { # If we match the 'from' pattern... if {[set idx [string first $from $line]] >= 0} { # Change for the 'to' replacement set line [string replace $line $idx [expr {$idx+$fl-1}] $to]
# Stop if we terminate, otherwise note that we've more work to do set any $more break; # Restart search for rules to apply } } #DEBUG# puts $line }
# Output the processed line puts $out $line
} close $out</lang> In the case where there are no terminating rules and no overlapping issues, the following is an alternative: <lang tcl>package require Tcl 8.5 if {$argc < 3} {error "usage: $argv0 ruleFile inputFile outputFile"} lassign $argv ruleFile inputFile outputFile
- Read the file of rules
set rules {} set f [open $ruleFile] foreach line [split [read $f] \n[close $f]] {
if {[string match "#*" $line] || $line eq ""} continue if {[regexp {^(.+)\s+->\s+(.*)$} $line -> from to]} { dict set rules $from $to } else { error "Syntax error: \"$line\"" }
}
- Apply the rules in a simplistic manner
set in [open $inputFile] set out [open $outputFile w] set data [read $in] close $in while 1 {
set newData [string map $rules $data] if {$newData eq $data} break set data $newData
} puts $out $data close $out</lang>
VBScript
Implementation
<lang vb> class markovparser
dim aRules public property let ruleset( sBlock ) dim i aRules = split( sBlock, vbNewLine ) '~ remove blank lines from end of array do while aRules( ubound( aRules ) ) = vbnullstring redim preserve aRules( ubound( aRules ) - 1 ) loop '~ parse array for i = lbound( aRules ) to ubound( aRules ) if left( aRules( i ), 1 ) = "#" then aRules( i ) = Array( vbnullstring, aRules(i)) else aRules( i ) = Split( aRules( i ), " -> ", 2 ) end if next end property public function apply( sArg ) dim ruleapplied dim terminator dim was dim i dim repl dim changes ruleapplied = true terminator = false
do while ruleapplied and (not terminator) changes = 0 was = sArg for i = lbound( aRules ) to ubound( aRules ) repl = aRules(i)(1) if left( repl, 1 ) = "." then terminator = true repl = mid( repl, 2 ) end if sArg = replace( sArg, aRules(i)(0), repl) if was <> sArg then changes = changes + 1 if changes = 1 then exit for end if end if if terminator then exit for end if next if changes = 0 then ruleapplied = false end if loop apply = sArg end function sub dump dim i for i = lbound( aRules ) to ubound( aRules ) wscript.echo eef(aRules(i)(0)=vbnullstring,aRules(i)(1),aRules(i)(0)& " -> " & aRules(i)(1)) & eef( left( aRules(i)(1), 1 ) = ".", " #terminator", "" ) next end sub private function eef( bCond, sExp1, sExp2 ) if bCond then eef = sExp1 else eef = sExp2 end if end function
end class </lang>
Invocation
<lang vb> dim m1 set m1 = new markovparser m1.ruleset = "# This rules file is extracted from Wikipedia:" & vbNewLine & _ "# http://en.wikipedia.org/wiki/Markov_Algorithm" & vbNewLine & _ "A -> apple" & vbNewLine & _ "B -> bag" & vbNewLine & _ "S -> shop" & vbNewLine & _ "T -> the" & vbNewLine & _ "the shop -> my brother" & vbNewLine & _ "a never used -> .terminating rule" wscript.echo m1.apply( "I bought a B of As from T S.")
dim m2 set m2 = new markovparser m2.ruleset = replace( "# Slightly modified from the rules on Wikipedia\nA -> apple\nB -> bag\nS -> .shop\nT -> the\nthe shop -> my brother\na never used -> .terminating rule", "\n", vbNewLine ) '~ m1.dump wscript.echo m2.apply( "I bought a B of As from T S.")
dim m3 set m3 = new markovparser m3.ruleset = replace("# BNF Syntax testing rules\nA -> apple\nWWWW -> with\nBgage -> ->.*\nB -> bag" & vbNewLine & _ "->.* -> money\nW -> WW\nS -> .shop\nT -> the\nthe shop -> my brother\na never used -> .terminating rule", "\n", vbNewLine ) wscript.echo m3.apply("I bought a B of As W my Bgage from T S.")
set m4 = new markovparser m4.ruleset = "### Unary Multiplication Engine, for testing Markov Algorithm implementations" & vbNewLine & _ "### By Donal Fellows." & vbNewLine & _ "# Unary addition engine" & vbNewLine & _ "_+1 -> _1+" & vbNewLine & _ "1+1 -> 11+" & vbNewLine & _ "# Pass for converting from the splitting of multiplication into ordinary" & vbNewLine & _ "# addition" & vbNewLine & _ "1! -> !1" & vbNewLine & _ ",! -> !+" & vbNewLine & _ "_! -> _" & vbNewLine & _ "# Unary multiplication by duplicating left side, right side times" & vbNewLine & _ "1*1 -> x,@y" & vbNewLine & _ "1x -> xX" & vbNewLine & _ "X, -> 1,1" & vbNewLine & _ "X1 -> 1X" & vbNewLine & _ "_x -> _X" & vbNewLine & _ ",x -> ,X" & vbNewLine & _ "y1 -> 1y" & vbNewLine & _ "y_ -> _" & vbNewLine & _ "# Next phase of applying" & vbNewLine & _ "1@1 -> x,@y" & vbNewLine & _ "1@_ -> @_" & vbNewLine & _ ",@_ -> !_" & vbNewLine & _ "++ -> +" & vbNewLine & _ "# Termination cleanup for addition" & vbNewLine & _ "_1 -> 1" & vbNewLine & _ "1+_ -> 1" & vbNewLine & _ "_+_ -> " '~ m4.dump wscript.echo m4.apply( "_1111*11111_")
set fso = createobject("scripting.filesystemobject") set m5 = new markovparser m5.ruleset = fso.opentextfile("busybeaver.tur").readall wscript.echo m5.apply("000000A000000") </lang>
Output
<lang vb> I bought a bag of apples from my brother. I bought a bag of apples from T shop. I bought a bag of apples with my money from T shop. 11111111111111111111 00011H1111000 </lang>
Wren
<lang ecmascript>import "/ioutil" for FileUtil, File import "/pattern" for Pattern
var lb = FileUtil.lineBreak
/* rulesets assumed to be separated by a blank line in file */ var readRules = Fn.new { |path|
return File.read(path).trimEnd().split("%(lb)%(lb)").map { |rs| rs.split(lb) }.toList
}
/* tests assumed to be on consecutive lines */ var readTests = Fn.new { |path| File.read(path).trimEnd().split(lb) }
var rules = readRules.call("markov_rules.txt") var tests = readTests.call("markov_tests.txt") var pattern = Pattern.new("+0/s[~.][+0/z]", Pattern.start) var ix = 0 for (origTest in tests) {
var captures = [] for (rule in rules[ix]) { if (rule.startsWith("#")) continue var splits = rule.split(" -> ") var m = pattern.find(splits[1]) if (m) captures.add([splits[0].trimEnd()] + m.capsText) } var test = origTest while (true) { var copy = test var redo = false for (c in captures) { test = test.replace(c[0], c[2]) if (c[1] == ".") break if (test != copy) { redo = true break } } if (!redo) break } System.print("%(origTest)\n%(test)\n") ix = ix + 1
}</lang>
- Output:
I bought a B of As from T S. I bought a bag of apples from my brother. I bought a B of As from T S. I bought a bag of apples from T shop. I bought a B of As W my Bgage from T S. I bought a bag of apples with my money from T shop. _1111*11111_ 11111111111111111111 000000A000000 00011H1111000
zkl
<lang zkl>fcn parseRuleSet(lines){
if(vm.numArgs>1) lines=vm.arglist; // lines or object ks:=L(); vs:=L(); foreach line in (lines){ if(line[0]=="#") continue; // nuke <comment> pattern,replacement:=line.replace("\t"," ") .split(" -> ",1).apply("strip"); ks.append(pattern); vs.append(replacement); } return(ks,vs);
}
fcn markov(text,rules){
ks,vs:=rules; eks:=ks.enumerate(); do{ go:=False; foreach n,k in (eks){ if (Void!=text.find(k)){ if (Void==(v:=vs[n])) return(text); if (v[0,1]==".") v=v[1,*] else go=True; text=text.replace(k,v,1); break; // restart after every rule application, unless terminating } } }while(go); text
}</lang> <lang zkl>ruleSet:=parseRuleSet("# This rules file is extracted from Wikipedia:",
"# http://en.wikipedia.org/wiki/Markov_Algorithm", "A\t->\tapple", "B -> bag", "S -> shop", "T -> the", "the shop -> my brother", "a never used -> .terminating rule");
ruleSet.println(); markov("I bought a B of As from T S.",ruleSet).println();</lang>
- Output:
L(L("A","B","S","T","the shop","a never used"),L("apple","bag","shop","the","my brother",".terminating rule")) I bought a bag of apples from my brother.
<lang zkl>parseRuleSet( // rule set in a list
T("# Slightly modified from the rules on Wikipedia", "A -> apple", "B -> bag", "S -> .shop", "T -> the", "the shop -> my brother", "a never used -> .terminating rule")) :
markov("I bought a B of As from T S.",_).println();
parseRuleSet("# BNF Syntax testing rules", "A -> apple",
"WWWW -> with", "Bgage -> ->.*", "B -> bag", "->.* -> money", "W -> WW", "S -> .shop", "T -> the", "the shop -> my brother", "a never used -> .terminating rule") :
markov("I bought a B of As W my Bgage from T S.",_).println();</lang>
- Output:
I bought a bag of apples from T shop. I bought a bag of apples with my money from T shop.
For the next two tasks, read the rule set from a file. <lang zkl>parseRuleSet(File("ruleSet4")) : markov("_1111*11111_",_).println(); parseRuleSet(File("ruleSet5")) : markov("000000A000000",_).println();</lang>
- Output:
11111111111111111111 00011H1111000
- WikipediaSourced
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